Gene marking

Cancer gene therapy update

Objective. To provide an update about gene marking and gene therapy trials in cancer patients.

Data Sources. A MEDLINE search using the term “gene therapy” was conducted for the period 1985 to 1998. The reference lists from retrieved articles were reviewed. Meeting abstracts from the American Society of Clinical Oncology annual meeting (published in their proceedings) and the Annual Cancer Gene Therapy Symposium (published in Cancer Gene Therapy) that concerned gene therapy in cancer patients were also included.

Data Extraction. Both authors reviewed the retrieved material and included preclinical data, case reports, and clinical trials related to gene transfer or gene therapy in cancer patients.

Data Synthesis. There are several possible approaches to using gene therapy for the diagnosis and treatment of cancer and for the monitoring of cancer therapy. Exogenous genes may be used to mark cells to help better understand cancer biology or may be used directly for cancer treatment. Gene-marking trials have already provided new information about cancer biology and have demonstrated that reinfused progenitor cells may be a source of relapse in patients with acute or chronic myelogenous leukemia and neuroblastoma.

Approaches using gene therapy for cancer treatment include: using lymphocytes as gene carriers, using foreign genes to increase tumor immunogenicity, introducing tumor regression antigen genes into viruses, introducing “sensitivity” genes to produce new cytotoxic agent(s) within tumors, producing new protein product(s) to protect normal cells, replacing missing or mutant tumor suppressor genes, and inactivating oncogenes. Clinical trials using these strategies have demonstrated that gene transfer is feasible (albeit with low transduction efficiency) and that gene expression occurs; in addition, clinical responses have been noted.

Genome walking in eukaryotes

Genome walking is a molecular procedure for the direct identification of nucleotide sequences from purified genomes. The only requirement is the availability of a known nucleotide sequence from which to start. Several genome walking methods have been developed in the last 20 years, with continuous improvements added to the first basic strategies, including the recent coupling with next generation sequencing technologies. This review focuses on the use of genome walking strategies in several aspects of the study of eukaryotic genomes. In a first part, the analysis of the numerous strategies available is reported. The technical aspects involved in genome walking are particularly intriguing, also because they represent the synthesis of the talent, the fantasy and the intelligence of several scientists. Applications in which genome walking can be employed are systematically examined in the second part of the review, showing the large potentiality of this technique, including not only the simple identification of nucleotide sequences but also the analysis of large collections of mutants obtained from the insertion of DNA of viral origin, transposons and transfer DNA (T-DNA) constructs. The enormous amount of data obtained indicates that genome walking, with its large range of applicability, multiplicity of strategies and recent developments, will continue to have much to offer for the rapid identification of unknown sequences in several fields of genomic research.

Noninvasive molecular neuroimaging using reporter genes: part II, experimental, current, and future applications

SUMMARY

In this second article, we review the various strategies and applications that make use of reporter genes for molecular imaging of the brain in living subjects. These approaches are emerging as valuable tools for monitoring gene expression in diverse applications in laboratory animals, including the study of gene-targeted and trafficking cells, gene therapies, transgenic animals, and more complex molecular interactions within the central nervous system. Further development of more sensitive and selective reporters, combined with improvements in detection technology, will consolidate the position of in vivo reporter gene imaging as a versatile technique for greater understanding of intracellular biologic processes and underlying molecular neuropathology and will potentially establish a future role in the clinical management of patients with neurologic diseases.

Molecular imaging of reporter gene expression in prostate cancer: an overview

Prostate cancer remains an important and growing health problem. Advances in imaging of prostate cancer may help to achieve earlier and more accurate diagnosis and treatment. We review the various strategies using reporter genes for molecular imaging of prostate cancer. These approaches are emerging as valuable tools for monitoring gene expression in laboratory animals and humans. Further development of more sensitive and selective reporters, combined with improvements in detection technology, will consolidate the position of reporter gene imaging as a versatile method for understanding of intracellular biological processes and the underlying molecular basis of prostate cancer, as well as potentially establishing a future role in the clinical management of patients afflicted with this disease.

Efficient lentiviral gene transfer to canine repopulating cells using an overnight transduction protocol

The use of lentiviral vectors for the transduction of hematopoietic stem cells has evoked much interest owing to their ability to stably integrate into the genome of nondividing cells. However, published large animal studies have reported highly variable gene transfer rates of typically less than 1%. Here we report the use of lentiviral vectors for the transduction of canine CD34+ hematopoietic repopulating cells using a very short, 18-hour transduction protocol. We compared lentiviral transduction of hematopoietic repopulating cells from either stem cell factor (SCF)– and granulocyte-colony stimulating factor (G-CSF)–primed marrow or mobilized peripheral blood in a competitive repopulation assay in 3 dogs. All dogs engrafted rapidly within 9 days. Transgene expression was detected in all lineages (B cells, T cells, granulocytes, and red blood cells as well as platelets) indicating multilineage engraftment of transduced cells, with overall long-term marking levels of up to 12%. Gene transfer levels in mobilized peripheral blood cells were slightly higher than in primed marrow cells. In conclusion, we show efficient lentiviral transduction of canine repopulating cells using an overnight transduction protocol. These results have important implications for the design of stem cell gene therapy protocols, especially for those diseases in which the maintenance of stem cells in culture is a major limitation.

Syngeneic bone marrow transduced with a recombinant retroviral vector to express endoplasmic reticulum signal-sequence-deleted major histocompatibility complex class-I alloantigen can induce specific immunologic unresponsiveness in vivo

BACKGROUND

Long-term survival of fully allogeneic cardiac grafts can be induced in mice through transduction of recipient bone marrow cells (BMCs) with a recombinant retroviral vector encoding a single full-length major histocompatibility complex (MHC) class I alloantigen. This study investigated whether cell surface expression of the transduced MHC antigen was necessary for the induction of specific unresponsiveness. METHOD The signal sequence for translocation into the endoplasmic reticulum was deleted from H-2K (SDELKb). Syngeneic BMCs from CBA.Ca (H2k) recipients were transduced with an MFG retroviral vector encoding either wild-type Kb or the mutant SDELKb and reinfused in conjunction with an anti-CD4 therapy. Four weeks later, the recipients underwent transplantation with a fully allogeneic C57BL/10 cardiac graft. Graft survival and the development of transplant arteriosclerosis were assessed.

RESULTS

Expression of both the wild-type Kb or SDELK in recipient CBA mice before transplantation resulted in prolonged survival of C57BL/10 grafts. Grafts from recipients pretreated with SDELKb developed 48%+/-22% intimal proliferation compared with 61%+/-21% in grafts from recipients pretreated with wild-type Kb. However, this difference did not reach statistical significance. CONCLUSION Cell surface expression, and therefore direct recognition, of an MHC class I alloantigen is not required to induce long-term survival of fully allogeneic cardiac grafts after retroviral transduction of recipient BMCs.

Highly efficient gene transfer into baboon marrow repopulating cells using GALV-pseudotype oncoretroviral vectors produced by human packaging cells

Vector-containing medium harvested from murine packaging cell lines has been shown to contain factors that can negatively influence the transduction and maintenance of hematopoietic stem cells. Thus, we generated a human packaging cell line with a gibbon ape leukemia virus pseudotype (Phoenix-GALV), and we evaluated vectors produced by Phoenix-GALV for their ability to transduce hematopoietic progenitor/stem cells. In 3 baboons, we used a competitive repopulation assay to directly compare GALV-pseudotype retrovirus vectors produced by either Phoenix-GALV or by the NIH 3T3-derived packaging cell line, PG13. In 3 additional baboons we compared Phoenix-GALV-derived vectors to more recently developed lentiviral vectors. Gene transfer efficiency into hematopoietic repopulating cells was assessed by evaluating the number of genetically modified peripheral blood and marrow cells using flow cytometry and real-time polymerase chain reaction. Transduction efficiency of hematopoietic repopulating cells was significantly higher using the Phoenix-GALV-derived vector as compared with the PG13-derived vectors or lentiviral vectors, with stable transduction levels up to 25%. We followed 2 animals for more than one year. Flow cytometric analysis of hematopoietic subpopulations in these animals revealed transgene expression in CD13(+) granulocytes, CD20(+) B lymphocytes, CD3(+) T lymphocytes, CD61(+) platelets, as well as red blood cells, indicating multilineage engraftment of cells transduced by Phoenix-GALV-pseudotype vectors. In addition, transduction of human CD34(+) cells was significantly more efficient than transduction of baboon CD34(+) cells, suggesting that Phoenix-GALV-derived oncoretroviral vectors may be even more efficient in human stem cell gene therapy applications.

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.

Expression of xenogeneic MHC class II molecules in HLA-DR(+) and -DR(-) cells: influence of retrovirus vector design and cellular context

We recently established that molecular chimeras of major histocompatibility complex (MHC) class II molecules, created via retroviral transfer of allogeneic class II cDNAs into bone marrow cells (BMCs), alleviated complications associated with mixed BMC chimeras while leading to T cell tolerance to renal grafts sharing the transferred class II. Initially demonstrated for allogeneic transplants in miniature swine, this concept was extended to T-dependent antibody (Ab) responses to xenogeneic antigens (Ags) in the pig --> baboon combination. Successful down-regulation of T cell responses appeared, however, to be contingent on a tight lineage-specific expression of transferred class II molecules. The present studies were, therefore, designed to evaluate the influence of construct design and cellular environment on expression of retrovirally transferred xenogeneic class II cDNAs. Proviral genomes for pig class II SLA-DR expression, differing only at the marker neo(r) or enhanced green fluorescent protein (EGFP) gene, showed increased membrane SLA-DR density on HLA-DR(-) fibroblasts as well as HLA-DR(+), TF-1 erythroleukemia cells. More importantly, HLA-DR(+) human B cell lines, although efficiently transduced with pig DR retroviruses, exhibited unstable surface pig DR. Surface pig DR- B cells, nevertheless, stimulated autologous human T cells pre-sensitized to pig Ags, a proliferation likely occurring through presentation of class II-derived peptides. Collectively, these data suggest that surface expression of transferred class II molecules is not related to the ability of recipient cells to synthesize xenogeneic class II molecules but rather to their Ag processing capacities.

[Contribution of antineoplastic biotherapy in the treatment of leukemia in children]

Improvements in the chemotherapeutic and transplant regimens have had a significant impact in improving survival rates for pediatric leukemia. However, there are still major problems to address including what options are available for patients with chemoresistant disease and what strategies are available to avoid toxicity associated with highly cytotoxic treatment regimens. Gene and immunotherapy protocols hold great promise. Using gene transfer of a marker gene, a number of biologic issues in the therapy of leukemia have been addressed. For example, by gene marking autologous bone marrow grafts it has been possible to demonstrate that infused marrow contributes to relapse in acute and chronic myeloid leukemias. In the allogeneic transplant setting, genetically modified T-cells have proven valuable for the prophylaxis and treatment of viral diseases and may have an important role in preventing or treating disease relapse. Gene transfer is also being used to modify tumor function, enhance immunogenicity, and confer drug-resistance to normal hematopoietic stem cells. With the continued scientific advancements in this field, gene therapy will almost certainly have a major impact on the treatment of pediatric leukemia in the future.

Tumor cell contamination in re-infused stem cell autografts: does it have clinical significance?

Tumor cells frequently contaminate autologous stem cell products in patients having a variety of malignancies. Mobilized peripheral blood stem cells may be less contaminated with tumor cells than bone marrow harvests are, but they are still frequently infiltrated. Gene-marking studies using retroviral vectors provide evidence that tumor cells contained in autografts contribute to relapse in myeloid leukemia and neuroblastoma patients. Also clinical studies have shown that tumor cell contamination of autografts is associated with shortened disease-free survival; on the other hand, successful ex vivo purging of tumor cells is associated with superior clinical outcome. However, the presence of tumor cells in autografts or insufficient purging may correlate with the extent of systemic residual disease and/or tumor chemosensitivity; therefore, there is no direct evidence that reinfused tumor cells alone cause relapse. Particularly in patients having highly chemosensitive disease and no detected systemic residual disease following high-dose transplant chemotherapy, the relative number of tumor cells contained in autografts and eventually reinfused, may become a determining factor for clinical outcome. There are no randomized trials showing improved (disease-free) survival with purging. In the absence of such trials, the contribution of tumor cells in the stem cell autografts to subsequent relapse remains controversial.

Update on the use of nonhuman primate models for preclinical testing of gene therapy approaches targeting hematopoietic cells

Transfer of genes into hematopoietic stem cells or primary lymphocytes has been a primary focus of the gene therapy field for more than a decade because of the wide variety of congenital and acquired diseases that potentially could be cured by successful gene transfer into these cell populations. However, despite success in murine models and in vitro, progress has been slow, and early clinical trials were disappointing due to inefficient gene transfer into long-term repopulating cells. The unique predictive value of nonhuman primate or other large animal models has become more apparent, and major advances in gene transfer efficiency have been made by utilizing these powerful but expensive and complex systems. This review summarizes more recent findings from nonhuman primate investigations focusing on hematopoietic stem cells or lymphocytes as target populations, and highlights specific preclinical issues, including safety. Results from studies using standard retroviral vectors, lentiviral vectors, adenoviral vectors, and adeno-associated viral vectors are discussed. Judicious application of these models should continue to be a priority, and advances should now be tested in proof-of-concept clinical trials.

The use of nonhuman primate models to improve gene transfer into haematopoietic stem cells

Primitive haematopoietic progenitor and stem cells (HSC) have been pursued as highly desirable targets for genetic therapy as technology allowing safe and controllable transfer of exogenous genes into eukaryotic cells was developed a decade ago. Retroviral vectors have been used for the majority of preclinical and clinical studies directed at these cells, because these vectors have a number of the necessary properties, including chromosomal integration, helper-free production systems, and lack of toxicity. Until recently, however, results with these vectors in clinical trials and large animal models indicated efficiency of gene transfer as a major hurdle to be overcome. We have focused on using the rhesus macaque autologous transplantation model to optimize gene transfer to primitive haematopoietic cells, and investigate questions regarding in vivo stem cell behaviour, in a system with proven predictive value for human haematopoiesis. By optimization of transduction conditions using standard vectors, gene transfer efficiency to primitive repopulating cells has reached the clinically relevant range of 5-20% long-term. Alternative vector systems, have also yielded promising results. We have also found that relatively simple manipulation of cell cycle status prior to reinfusion of marked cells results in significantly improved engraftment of transduced cells: this finding may have an impact particularly in the nonablative setting. The high level marking has permitted insertion site analysis and clonal tracking in vivo. Inverse PCR and/or a ligation-mediated PCR procedure have demonstrated that a large number of transduced clones (over 50) contribute to multiple lineages in vivo for up to at least 2 years post-transplantation. Thus far we have little evidence for rapid clonal succession or lineage-restricted engraftment of transduced cells. These and other advances should result in successful gene therapy for a variety of acquired and congenital disorders affecting HSCs and their progeny lineages.

Gene transfer and the treatment of haematological malignancy

Gene therapy offers an additional therapeutic modality for treating haematological malignancy. Because gene therapies could be truly specific for the malignancy, they should ultimately prove both safe and effective. We have far to go before this full potential is realized, but gene transfer strategies are already showing therapeutic promise. Gene transfer may be used to correct the genetic defect in the tumour, to render it more susceptible to conventional therapies, or the normal host cells more resistant, to induce or amplify an antitumour immune response, or simply as a means of tracking the tumour or cells used for treatment. This article describes examples of each approach and discusses future prospects for the field.

Clinical Gene Therapy in Hematology: Past and Future

Gene transfer into hematopoietic cells using viral vectors has focused mostly on lymphocytes and hematopoietic stem cells (HSCs). HSCs have been considered particularly important as target cells because of their pluripotency and ability to reconstitute hematopoiesis after myeloablation and transplantation. HSCs are believed to have the ability to live a long time, perhaps a lifetime, in the recipient following bone marrow transplantation. Genetic correction of HSCs can therefore potentially last a lifetime and permanently cure hematologic disorders in which genetic deficiencies cause the pathology. Oncoretroviral vectors have been the main vectors used for HSCs because of their ability to integrate into the chromosomes of their target cells. Gene-transfer efficiency of murine HSCs is high using oncoretroviral vectors. In contrast, gene-transfer efficiency using the same viral vectors to transduce human HSCs or HSCs from large animals has been much lower. Although these difficulties may have several causes, the main reason for the low efficiency of human HSC transduction with oncoretroviral vectors is probably because of the nondividing nature of HSCs. Murine HSCs can be easily stimulated to divide in culture, whereas it is more problematic to stimulate human HSCs to divide rapidly in vitro. Because oncoretroviral vectors require dividing target cells for successful nuclear import of the preintegration complex and subsequent integration of the provirus, only the dividing fraction of the target cells can be transduced. This review focuses on gene transfer into human hematopoietic cells, particularly human HSCs. We review the clinical studies that have been reported, including the recent successful gene therapy for X-linked severe combined immunodeficiency. We discuss how the gene-transfer efficiency of human HSCs can be improved using oncoretroviral and lentiviral vectors.

Gene-Marking studies of hematopoietic cells

Gene-marking studies were the first approved clinical protocols introducing exogenous genetic material into human cells. Such studies were never intended to provide direct therapeutic benefit. Instead, they were expected to provide information about normal cell biology and disease pathogenesis that could not be obtained in any other way. However, the information gained from such studies has had a significant impact on disease management. Gene-marking studies have provided valuable insights into the biology of the human stem cell, factors that influence the efficiency of gene transfer, mechanisms of relapse after stem cell transplantation, and the pharmacodynamics of adoptive cellular immunotherapy. With continuing advances in gene-marking technology, the value of the information provided by these studies increases, thereby ensuring their continued relevance to the field of gene transfer.

High-dose chemotherapy and stem cell transplantation for patients with stage IV breast cancer without clinically evident disease: correlation of CD34+ selection to clinical outcome

Forty-five patients with metastatic breast cancer without clinically evident disease were treated with thiotepa 750 mg/m2, mitoxantrone 40 mg/m2 and carboplatin 1000 mg/m2 followed by stem cell transplantation to determine the safety and efficacy of CD34+ selection of peripheral blood stem cells. Of these, 15 patients' (group I) stem cells were processed through Baxter Isolex 300 device for CD34+ selection, whereas 30 patients (group II) received unmanipulated stem cells. Toxicity, progression-free survival and survival were compared between these two groups. There was no difference in transfusion requirements, white cell count and platelet recovery and non-hematologic toxicity between the two groups. The survival of patients in group I was 27 months compared to 38 months in group II (P = 0.8). The progression-free survival was 12 months and 13.5 months for group I and group II patients, respectively (P = 0.6). Our results indicate that while there is no adverse effect, there is also no significant advantage of CD34+ selection in terms of progression-free survival and survival in patients with metastatic breast cancer without clinically evident disease. Bone Marrow Transplantation (2000).

Accurate estimation of transduction efficiency necessitates a multiplex real-time PCR

Transduction efficiency can be easily monitored during pre-clinical trials by inclusion of marker genes. However, the use of such marker genes should be avoided in the final clinical gene therapy application since their products are often immunogenic, making it difficult to monitor transduction, especially if the vector is applied in vivo. In these cases PCR-based methods like the real-time PCR might provide a powerful tool to estimate biodistribution. To investigate the accuracy of this method, we have developed and tested a real-time PCR assay for the quantification of the enhanced green fluorescent protein (EGFP) gene and compared the results with transduction efficiencies estimated by FACS analysis. Although our real-time PCR assay itself was characterized by a high precision over a wide dynamic range of quantification, significant differences in the transduction efficiency compared with FACS data were initially observed. Accurate determination could only be achieved using an optimized multiplex real-time PCR assay, which allows the simultaneous calculation of cell number and EGFP copy number in the same tube. In view of future needs for methods allowing precise and accurate analysis of biodistribution in gene therapy trials, our data highlight the necessity critically to check both parameters in the implemented assay.

Distinct Requirements for Optimal Growth and In Vitro Expansion of Human CD34+CD38− Bone Marrow Long-Term Culture-Initiating Cells (LTC-IC), Extended LTC-IC, and Murine In Vivo Long-Term Reconstituting Stem Cells

Recently, primitive human bone marrow (BM) progenitors supporting hematopoiesis in extended (>60 days) long-term BM cultures were identified. Such extended long-term culture-initiating cells (ELTC-IC) are of the CD34+CD38− phenotype, are quiescent, and are difficult to recruit into proliferation, implicating ELTC-IC as the most primitive human progenitor cells detectable in vitro. However, it remains to be established whether ELTC-IC can proliferate and potentially expand in response to early acting cytokines. Here, CD34+CD38− BM ELTC-IC (12-week) were efficiently recruited into proliferation and expanded in vitro in response to early acting cytokines, but conditions for expansion of ELTC-IC activity were distinct from those of traditional (5-week) LTC-IC and murine long-term repopulating cells. Whereas c-kit ligand (KL), interleukin-3 (IL-3), and IL-6 promoted proliferation and maintenance or expansion of murine long-term reconstituting activity and human LTC-IC, they dramatically depleted ELTC-IC activity. In contrast, KL, flt3 ligand (FL), and megakaryocyte growth and development factor (MGDF) (and KL + FL + IL-3) expanded murine long-term reconstituting activity as well as human LTC-IC and ELTC-IC. Expansion of LTC-IC was most optimal after 7 days of culture, whereas optimal expansion of ELTC-IC activity required 12 days, most likely reflecting the delayed recruitment of quiescent CD34+CD38− progenitors. The need for high concentrations of KL, FL, and MGDF (250 ng/mL each) and serum-free conditions was more critical for expansion of ELTC-IC than of LTC-IC. The distinct requirements for expansion of ELTC-IC activity when compared with traditional LTC-IC suggest that the ELTC-IC could prove more reliable as a predictor for true human stem cell activity after in vitro stem cell manipulation.

Distinct Requirements for Optimal Growth and In Vitro Expansion of Human CD34+CD38− Bone Marrow Long-Term Culture-Initiating Cells (LTC-IC), Extended LTC-IC, and Murine In Vivo Long-Term Reconstituting Stem Cells

Recently, primitive human bone marrow (BM) progenitors supporting hematopoiesis in extended (>60 days) long-term BM cultures were identified. Such extended long-term culture-initiating cells (ELTC-IC) are of the CD34+CD38− phenotype, are quiescent, and are difficult to recruit into proliferation, implicating ELTC-IC as the most primitive human progenitor cells detectable in vitro. However, it remains to be established whether ELTC-IC can proliferate and potentially expand in response to early acting cytokines. Here, CD34+CD38− BM ELTC-IC (12-week) were efficiently recruited into proliferation and expanded in vitro in response to early acting cytokines, but conditions for expansion of ELTC-IC activity were distinct from those of traditional (5-week) LTC-IC and murine long-term repopulating cells. Whereas c-kit ligand (KL), interleukin-3 (IL-3), and IL-6 promoted proliferation and maintenance or expansion of murine long-term reconstituting activity and human LTC-IC, they dramatically depleted ELTC-IC activity. In contrast, KL, flt3 ligand (FL), and megakaryocyte growth and development factor (MGDF) (and KL + FL + IL-3) expanded murine long-term reconstituting activity as well as human LTC-IC and ELTC-IC. Expansion of LTC-IC was most optimal after 7 days of culture, whereas optimal expansion of ELTC-IC activity required 12 days, most likely reflecting the delayed recruitment of quiescent CD34+CD38− progenitors. The need for high concentrations of KL, FL, and MGDF (250 ng/mL each) and serum-free conditions was more critical for expansion of ELTC-IC than of LTC-IC. The distinct requirements for expansion of ELTC-IC activity when compared with traditional LTC-IC suggest that the ELTC-IC could prove more reliable as a predictor for true human stem cell activity after in vitro stem cell manipulation.

Ex Vivo Expansion of Autologous Bone Marrow CD34+ Cells With Porcine Microvascular Endothelial Cells Results in a Graft Capable of Rescuing Lethally Irradiated Baboons

Hematopoietic stem cell (HSC) self-renewal in vitro has been reported to result in a diminished proliferative capacity or acquisition of a homing defect that might compromise marrow repopulation. Our group has demonstrated that human HSC expanded ex vivo in the presence of porcine microvascular endothelial cells (PMVEC) retain the capacity to competitively repopulate human bone fragments implanted in severe combined immunodeficiency (SCID) mice. To further test the marrow repopulating capacity of expanded stem cells, our laboratory has established a myeloablative, fractionated total body irradiation conditioning protocol for autologous marrow transplantation in baboons. A control animal, which received no transplant, as well as two animals, which received a suboptimal number of marrow mononuclear cells, died 37, 43, and 59 days postirradiation, respectively. Immunomagnetically selected CD34+ marrow cells from two baboons were placed in PMVEC coculture with exogenous human cytokines. After 10 days of expansion, the grafts represented a 14-fold to 22-fold increase in cell number, a 4-fold to 5-fold expansion of CD34+ cells, a 3-fold to 4-fold increase of colony-forming unit–granulocyte-macrophage (CFU-GM), and a 12-fold to 17-fold increase of cobblestone area-forming cells (CAFC) over input. Both baboons became transfusion independent by day 23 posttransplant and achieved absolute neutrophil count (ANC) >500/μL by day 25 ± 1 and platelets >20,000/μL by day 29 ± 2. This hematopoietic recovery was delayed in comparison to two animals that received either a graft consisting of freshly isolated, unexpanded CD34+ cells or 175 × 106/kg unfractionated marrow mononuclear cells. Analysis of the proliferative status of cells in PMVEC expansion cultures demonstrated that by 10 days, 99.8% of CD34+ cells present in the cultures had undergone cycling, and that the population of cells expressing a CD34+ CD38− phenotype in the cultures was also the result of active cell division. These data indicate that isolated bone marrow CD34+ cells may undergo cell division during ex vivo expansion in the presence of endothelial cells to provide a graft capable of rescuing a myeloablated autologous host.

No discrepancy between in vivo gene marking efficiency assessed in peripheral blood populations compared with bone marrow progenitors or CD34+ cells

Reports of 1- to 2-log higher gene transfer levels in purified CD34+ cells or marrow CFU compared with levels in mature circulating blood cells after transplantation of retrovirally transduced primitive human hematopoietic cells have resulted in concern that transduced progenitors do not contribute proportionally to ongoing hematopoiesis (Kohn et al., 1995; Brenner, 1996). To study the issue in a relevant large animal, we analyzed samples of mature blood cells, marrow CD34-enriched cells and marrow CD34-depleted cells, and marrow CFU from a cohort of 11 rhesus transplanted with retrovirally transduced cells and followed for up to 5.5 years. They were transplanted with CD34-enriched bone marrow (BM) or G-CSF/SCF-mobilized peripheral blood (PB) cells transduced with vectors containing either neo, human glucocerebrosidase, or murine adenosine deaminase genes. There were no significant differences between the levels of vector sequences found in BM CD34+ cells, BM CD34- cells, PB granulocytes, or PB mononuclear cells (MNCs) in any animal. In four animals transplanted with SCF/G-CSF-primed BM cells and analyzed 3-6 months posttransplantation, the percentage of CFU containing the neo vector appeared to be 1 log higher than the representation of marked cells in the PB of these animals, but this discrepancy did not persist at time points greater than 6 months posttransplantation. The level of CFU marking was no higher than PB granulocyte or MNC marking at any time points in the other animals. Low levels of mature gene-modified cells probably reflect poor transduction of repopulating stem cells, not a block in differentiation or specific immune rejection of mature cells. This study represents the longest follow-up of primates transplanted with transduced hematopoietic cells, and it is encouraging that the levels of vector-containing cells appear stable for up to 5 years.

A simple and efficient purification of transduced cells by using green fluorescent protein gene as a selection marker

BACKGROUND

Simple and efficient method for the selection of transduced cells would greatly facilitate the clinical utilization of retrovirus vectors. We developed a therapeutic bicistronic retrovirus vector for Gaucher disease, MFG-GC-GFP, which contains the human glucocerebrosidase (GC) gene and the green fluorescent protein (GFP) gene of the jellyfish Aequorea victoria as a vital selection marker, and investigated its applicability as gene therapy for Gaucher disease.

METHODS AND RESULTS

A packaging cell line, GP + envAM12, was transfected with MFG-GC-GFP and, thus, produced a high titer recombinant virus (1.0 x 10(6) c.f.u./mL) in the culture supernatant. The expression level of GFP was correlated with the virus production in cells. The recombinant virus infected skin fibroblasts from a Gaucher patient and a sorted fraction of the cells expressing GFP by flow cytometry exhibited almost a six-fold higher activity of GC than normal fibroblasts.

CONCLUSIONS

These data indicate that MFG-GC-GFP enables the one-step purification of a transduced fraction of target cells and is, therefore, considered to be a useful therapeutic vector for the experimental gene therapy of Gaucher disease.

Retroviral transfer of the glucocerebrosidase gene into CD34+ cells from patients with Gaucher disease: in vivo detection of transduced cells without myeloablation

Retroviral gene transfer of the glucocerebrosidase gene to hematopoietic progenitor and stem cells has shown promising results in animal models and corrected the enzyme deficiency in cells from Gaucher patients in vitro. Therefore, a clinical protocol was initiated to explore the safety and feasibility of retroviral transduction of peripheral blood (PB) or bone marrow (BM) CD34+ cells with the G1Gc vector. This vector uses the viral LTR promoter to express the human glucocerebrosidase cDNA. Three adult patients have been entered with follow-up of 6-15 months. Target cells were G-CSF-mobilized and CD34-enriched PB cells or CD34-enriched steady state BM cells, and were transduced ex vivo for 72 hr. Patient 1 had PB cells transduced in the presence of autologous stromal marrow cells. Patient 2 had PB cells transduced in the presence of autologous stroma, IL-3, IL-6, and SCF. Patient 3 had BM cells transduced in the presence of autologous stroma, IL-3, IL-6, and SCF. At the end of transduction, the cells were collected and infused immediately without any preparative treatment of the patients. The transduction efficiency of the CD34+ cells at the end of transduction was approximately 1, 10, and 1 for patients 1, 2, and 3, respectively, as estimated by semiquantitative PCR on bulk samples and PCR analysis of individual hematopoietic colonies. Gene marking in vivo was demonstrated in patients 2 and 3. Patient 2 had vector-positive PB granulocytes and mononuclear bone marrow cells at 1 month postinfusion and positive PB mononuclear cells at 2 and 3 months postinfusion. Patient 3 had a positive BM sample at 1 month postinfusion but was negative thereafter. These results indicate that gene-marked cells can engraft and persist for at least 3 months postinfusion, even without myeloablation. However, the level of corrected cells (<0.02%) is too low to result in any clinical benefit, and glucocerebrosidase enzyme activity did not increase in any patient following infusion of transduced cells. Modifications of vector systems and transduction conditions, along with partial myeloablation to allow higher levels of engraftment, may be necessary to achieve beneficial levels of correction in patients with Gaucher disease.

Gene therapy for leukemia and lymphoma

Gene therapy of malignant diseases can be divided into four basic approaches: gene interference, gene insertion, immunopotentiation, and suicide gene approaches. This article reviews the application of these approaches in the therapy of leukemias and lymphomas.

Murine bone marrow expressing the neomycin resistance gene has no competitive disadvantage assessed in vivo

The neomycin phosphotransferase (neo) gene is one of the most common marker genes used in gene transfer experimentation, but potential effects of neo gene expression in vivo have not been systematically investigated. Several early clinical retroviral gene transfer studies have suggested that neo gene expression could have deleterious effects on hematopoiesis, owing to a discrepancy between the level of neo-marked transduced marrow progenitor cells compared with mature circulating progeny cells posttransplantation (Brenner et al., 1993; Kohn et al., 1995; Brenner, 1996b). We examined the long-term in vivo repopulating ability of bone marrow from transgenic mice expressing neo from a strong constitutive promoter using a competitive repopulation assay. Different ratios of neo transgenic and wild-type congenic marrow cells were cotransplanted into W/Wv recipient mice. The percentages of blood cells containing the neo transgene in each group of recipient mice monitored for 4 months posttransplantation closely matched the input ratios of neo transgenic to congenic control marrow cells. Similar concordances of engraftment with input ratios of neo transgenic cells were also found in spleen, thymus, and whole marrow of recipient mice at 4 months posttransplantation. Analysis of the beta-hemoglobin phenotype (beta(single) for the neo transgenic and C57 control cells and beta(diffuse) for the congenic competitor HW80 cells) in recipients confirmed erythroid repopulation from neo transgenic marrow cells at levels matching the input ratios. We conclude that hematopoietic cells expressing neo had no engraftment or maturation defects detectable in vivo. These results suggest that the low-level contribution of vector-marked cells to circulating populations in clinical trials is not due to direct deleterious effects of neo gene expression on hematopoiesis.

The influence of patient-related factors on ex vivo retroviral-mediated gene transfer into mobilized peripheral blood myeloid progenitors

Mobilized human peripheral blood progenitor cells are potential alternatives to bone marrow cells as targets for ex vivo gene transfer. We report the transduction efficiency of retroviral-mediated gene transfer into myeloid progenitors of peripheral blood progenitor cell (PBPC) harvests, mobilized by high-dose cyclophosphamide and GM-CSF, compared with nonmobilized bone marrow (BM). Eleven PBPC samples were enriched for CD34+ cells, preincubated with IL-3 (10 ng/ml), IL-6 (50 ng/ml), and 10% autologous plasma for 42 hr, and transduced over a 6-hr incubation with IL-3 + IL-6 and a retroviral vector carrying the NeoR gene. NeoR-specific sequences were detected by polymerase chain reaction in 10 cell pellets (91%). Gene expression in CFU-GM colonies was found in nine transduced samples (82%), with a mean transduction efficiency of 5.2% (95% CI, 1.3-11.8%) CFU-GM per PBPC sample. In univariate analysis, a higher transduction efficiency into CFU-GM correlated significantly with a higher CFU-GM concentration in the CD34+-enriched sample (p = 0.009), a shorter interval from diagnosis (p < 0.001), and fewer months of prior cytotoxic treatment (p = 0.001); correlation with younger age was of borderline statistical significance (p = 0.077). In multivariate analysis a shorter interval from diagnosis and, to a lesser degree, a higher CFU-GM concentration in the CD34+-enriched sample were independent predictors of higher transduction efficiency. Twelve BM samples were similarly transduced; 11 pellets were PCR positive. CFU-GM NeoR gene expression was 4.2% (95% CI, 2.0-7.2%) CFU-GM per BM sample, which was not significantly different from the transduction efficiency into PBPC cells. No correlation was found between the transduction efficiency of CFU-GM in BM samples and CFU-GM concentration in the CD34+-enriched sample, time from diagnosis, months of prior cytotoxic treatment, and/or patient age. Our data suggest that the transduction efficiency ex vivo may be influenced by time from diagnosis, CFU-GM concentration in the sample, and possibly by the extent of prior cytotoxic administration.

Retroviral-Mediated Transfer of the Green Fluorescent Protein Gene Into Murine Hematopoietic Cells Facilitates Scoring and Selection of Transduced Progenitors In Vitro and Identification of Genetically Modified Cells In Vivo

We have investigated the utility of the green fluorescent protein (GFP) to serve as a marker to assess retroviral gene transfer into hematopoietic cells and as a tool to identify and enrich for cells expressing high levels of the vector-encoded transcript. GFP, by virtue of a naturally occurring chromophore encoded in its primary sequence, displays autonomous fluorescence, thus eliminating the need for antibody or cytochemical staining to detect its expression. A bicistronic murine stem cell virus (MSCV)-based retroviral vector was constructed containing the GFP cDNA and a mutant, human dihydrofolate reductase gene. High-titer, ecotropic retroviral producer cells free of replication competent virus were generated and used to transduce murine bone marrow cells by cocultivation. Within 24 hours after completion of the transduction procedure, a high proportion (40% to 70%) of the marrow cells were intensely fluorescent compared to mock-transduced cells or cells transduced with a control retrovirus. Erythroid and myeloid hematopoietic colonies derived from GFP-transduced marrow were easily scored for retroviral gene transfer by direct in situ fluorescence microscopy. Clonogenic progenitors expressing increased levels of antifolate drug resistance could be enriched from the GFP-transduced marrow population by fluorescence activated cell sorting of cells expressing high levels of GFP. In vivo, splenic hematopoietic colonies and peripheral blood cells from animals transplanted with GFP-transduced marrow displayed intense fluorescence. These results show that GFP is an excellent marker for scoring and tracking gene-modified hematopoietic cells and for allowing rapid selection and enrichment of transduced cells expressing high levels of the transgene.