Reduction in hematopoietic stem cell numbers with in vivo drug selection can be partially abrogated by HOXB4 gene expression.

In vivo selection of hematopoietic stem cells (HSCs) offers an approach to enrichment of genetically modified blood cells in the context of gene therapy for blood disorders. We have previously demonstrated efficient HSC selection in mice using retroviral vectors expressing dihydrofolate reductase (DHFR) or methylguanine methyltransferase (MGMT) drug resistance genes. In this study, we examined whether drug selection was followed by subsequent HSC regeneration and, if not, whether regeneration could be augmented by enforced expression of HOXB4, which has previously been shown to enhance HSC regeneration after transplant. Using a murine competitive repopulation model, we found that selection using either the DHFR or the MGMT system was accompanied by a significant overall reduction in repopulating activity in secondary transplant assays, although hematopoiesis remained normal after recovery. Inclusion of a HOXB4 expression cassette in the DHFR vector resulted in a partial restoration of HSC numbers following selection and was associated with an increase in HSC selection efficiency. These results illustrate that while drug resistance vectors can protect transduced HSC from cytotoxic drugs, the self-renewal capacity of transduced HSCs is limited following in vivo selection. Strategies that increase self-renewal capacity could increase the efficiency and safety of in vivo selection.

Targeting gene-modified hematopoietic cells to the central nervous system: use of green fluorescent protein uncovers microglial engraftment.

Gene therapy in the central nervous system (CNS) is hindered by the presence of the blood-brain barrier, which restricts access of serum constituents and peripheral cells to the brain parenchyma. Expression of exogenously administered genes in the CNS has been achieved in vivo using highly invasive routes, or ex vivo relying on the direct implantation of genetically modified cells into the brain. Here we provide evidence for a novel, noninvasive approach for targeting potential therapeutic factors to the CNS. Genetically-modified hematopoietic cells enter the CNS and differentiate into microglia after bone-marrow transplantation. Up to a quarter of the regional microglial population is donor-derived by four months after transplantation. Microglial engraftment is enhanced by neuropathology, and gene-modified myeloid cells are specifically attracted to the sites of neuronal damage. Thus, microglia may serve as vehicles for gene delivery to the nervous system.

Neogenesis of cerebellar Purkinje neurons from gene-marked bone marrow cells in vivo.

The versatility of stem cells has only recently been fully recognized. There is evidence that upon adoptive bone marrow (BM) transplantation (BMT), donor-derived cells can give rise to neuronal phenotypes in the brains of recipient mice. Yet only few cells with the characteristic shape of neurons were detected 1-6 mo post-BMT using transgenic or newborn mutant mice. To evaluate the potential of BM to generate mature neurons in adult C57BL/6 mice, we transferred the enhanced green fluorescent protein (GFP) gene into BM cells using a murine stem cell virus-based retroviral vector. Stable and high level long-term GFP expression was observed in mice transplanted with the transduced BM. Engraftment of GFP-expressing cells in the brain was monitored by intravital microscopy. In a long-term follow up of 15 mo post-BMT, fully developed Purkinje neurons were found to express GFP in both cerebellar hemispheres and in all chimeric mice. GFP-positive Purkinje cells were also detected in BM chimeras from transgenic mice that ubiquitously express GFP. Based on morphologic criteria and the expression of glutamic acid decarboxylase, the newly generated Purkinje cells were functional.

Functional requirements for phenotypic correction of murine beta-thalassemia: implications for human gene therapy.

As initial human gene therapy trials for beta-thalassemia are contemplated, 2 critical questions important to trial design and planning have emerged. First, what proportion of genetically corrected hematopoietic stem cells (HSCs) will be needed to achieve a therapeutic benefit? Second, what level of expression of a transferred globin gene will be required to improve beta-thalassemic erythropoiesis? These questions were directly addressed by means of a murine model of severe beta-thalassemia. Generation of beta-thalassemic mice chimeric for a minority proportion of genetically normal HSCs demonstrated that normal HSC chimerism levels as low as 10% to 20% resulted in significant increases in hemoglobin (Hb) level and diminished extramedullary erythropoiesis. A large majority of the peripheral red cells in these mice were derived from the small minority of normal HSCs. In a separate set of independent experiments, beta-thalassemic mice were bred with transgenic mice that expressed different levels of human globins. Human gamma-globin messenger RNA (mRNA) expression at 7% of the level of total endogenous alpha-globin mRNA in thalassemic erythroid cells resulted in improved red cell morphology, a greater than 2-g/dL increase in Hb, and diminished reticulocytosis and extramedullary erythropoiesis. Furthermore, gamma-globin mRNA expression at 13% resulted in a 3-g/dL increase in Hb and nearly complete correction of red cell morphology and other indices of inefficient erythropoiesis. These data indicate that a significant therapeutic benefit could be achieved with expression of a transferred globin gene at about 15% of the level of total alpha-globin mRNA in patients with severe beta-thalassemia in whom 20% of erythroid precursors express the vector genome.

High levels of lymphoid expression of enhanced green fluorescent protein in nonhuman primates transplanted with cytokine-mobilized peripheral blood CD34(+) cells.

We have used a murine retrovirus vector containing an enhanced green fluorescent protein complimentary DNA (EGFP cDNA) to dynamically follow vector-expressing cells in the peripheral blood (PB) of transplanted rhesus macaques. Cytokine mobilized CD34(+) cells were transduced with an amphotropic vector that expressed EGFP and a dihydrofolate reductase cDNA under control of the murine stem cell virus promoter. The transduction protocol used the CH-296 recombinant human fibronectin fragment and relatively high concentrations of the flt-3 ligand and stem cell factor. Following transplantation of the transduced cells, up to 55% EGFP-expressing granulocytes were obtained in the peripheral circulation during the early posttransplant period. This level of myeloid marking, however, decreased to 0.1% or lower within 2 weeks. In contrast, EGFP expression in PB lymphocytes rose from 2%-5% shortly following transplantation to 10% or greater by week 5. After 10 weeks, the level of expression in PB lymphocytes continued to remain at 3%-5% as measured by both flow cytometry and Southern blot analysis, and EGFP expression was observed in CD4(+), CD8(+), CD20(+), and CD16/56(+) lymphocyte subsets. EGFP expression was only transiently detected in red blood cells and platelets soon after transplantation. Such sustained levels of lymphocyte marking may be therapeutic in a number of human gene therapy applications that require targeting of the lymphoid compartment. The transient appearance of EGFP(+) myeloid cells suggests that transduction of a lineage-restricted myeloid progenitor capable of short-term engraftment was obtained with this protocol. (Blood. 2000;95:445-452)

Fv2 encodes a truncated form of the Stk receptor tyrosine kinase.

The Friend virus susceptibility 2 (Fv2) locus encodes a dominant host factor that confers susceptibility to Friend virus-induced erythroleukaemia in mice. We mapped Fv2 to a 1.0-Mb interval that also contained the gene (Ron) encoding the stem cell kinase receptor (Stk). A truncated form of Stk (Sf-stk), which was the most abundant form of Stk in Fv2-sensitive (Fv2ss) erythroid cells, was not expressed in Fv2 resistant (Fv2rr) cells. Enforced expression of Sf-stk conferred susceptibility to Friend disease, whereas targeted disruption of Ron caused resistance. We conclude that the Fv2 locus encodes Ron, and that a naturally expressed, truncated form of Stk confers susceptibility to Friend virus-induced erythroleukaemia.

Adenovirus-mediated expresssion of the murine ecotropic receptor facilitates transduction of human hematopoietic cells with an ecotropic retroviral vector.

One factor limiting the ability to modify human repopulating hematopoietic cells genetically with retroviral vectors is the relatively low expression of the cognate viral receptor. We have tested sequential transduction of human hematopoietic cells with an adenoviral vector encoding the ecotropic retroviral receptor followed by transduction with an ecotropic retroviral vector. Adenoviral transduction of K562 erythroleukemia cells was highly efficiently with >95% of cells expressing the ecotropic receptor at a multiplicity of infection (MOI) of 103with a correspondingly high transduction with a retroviral vector. Ecotropic receptor expression in CD34+ cells following transduction with adenoviral vectors was increased by at least two-fold (from 20 to 48%) by replacing the RSV promoter with the CMV E1a promoter, resulting in a parallel increase in retroviral transduction efficiency. Replacing the head portion of the fiber protein in conventional adenoviral vectors (serotype 5) with the corresponding portion from an adenoviral 3 serotype resulted in ecotropic receptor expression in 60% of CD34+ cells at an MOI of 104 and a retroviral transduction of 60% of hematopoietic clonogenic progenitors. The sequential transduction strategy also resulted in efficient transduction of the primitive CD34+CD38- subset suggesting that it may hold promise for genetic modification of human hematopoietic stem cells.

High-efficiency transduction and long-term gene expression with a murine stem cell retroviral vector encoding the green fluorescent protein in human marrow stromal cells.

Bone marrow stromal cells (MSCs) are unique mesenchymal cells that have been utilized as vehicles for the delivery of therapeutic proteins in gene therapy protocols. However, there are several unresolved issues regarding their potential therapeutic applications. These include low transduction efficiency, attenuation of transgene expression, and the technical problems associated with drug-based selection markers. To address these issues, we have developed a transduction protocol that yields high-level gene transfer into human MSCs, employing a murine stem cell virus-based bicistronic vector containing the green fluorescent protein (GFP) gene as a selectable marker. Transduction of MSCs plated at low density for 6 hr per day for 3 days with high-titer viral supernatant resulted in a gene transfer efficiency of 80+/-6% (n = 10) as measured by GFP fluorescence. Neither centrifugation nor phosphate depletion increased transduction efficiency. Assessment of amphotropic receptor (Pit-2) expression by RT-PCR demonstrated that all MSCs expressing the receptor were successfully transduced. Cell cycle distribution profiles measured by propidium iodide staining showed no correlation with the susceptibility of MSCs to transduction by the retroviral vector. Human MSCs sequentially transduced with an adenoviral vector encoding the ecotropic receptor and ecotropic retroviral vector encoding GFP demonstrated that all MSCs are susceptible to retroviral transduction. We further showed that both genes of bicistronic vector are expressed for at least 6 months in vitro and that transgene expression did not affect the growth or osteogenic differentiation potential of MSCs. Future studies will be directed toward the development of gene therapy protocols employing this strategy.

Enforced expression of the GATA-2 transcription factor blocks normal hematopoiesis.

The zinc finger transcription factor GATA-2 is highly expressed in immature hematopoietic cells and declines with blood cell maturation. To investigate its role in normal adult hematopoiesis, a bicistronic retroviral vector encoding GATA-2 and the green fluorescent protein (GFP) was used to maintain the high levels of GATA-2 that are normally present in primitive hematopoietic cells. Coexpression of the GFP marker facilitated identification and quantitation of vector-expressing cells. Bone marrow cells transduced with the GATA-2 vector expressed GFP as judged by flow cytometry and GATA-2 as assessed by immunoblot analysis. A 50% to 80% reduction in hematopoietic progenitor-derived colony formation was observed with GATA-2/GFP-transduced marrow, compared with marrow transduced with a GFP-containing vector lacking the GATA-2 cDNA. Culture of purified populations of GATA-2/GFP-expressing and nonexpressing cells confirmed a specific ablation of the colony-forming ability of GATA-2/GFP-expressing progenitor cells. Similarly, loss of spleen colony-forming ability was observed for GATA-2/GFP-expressing bone marrow cells. Despite enforced GATA-2 expression, marrow cells remained viable and were negative in assays to evaluate apoptosis. Although efficient transduction of primitive Sca-1(+) Lin- cells was observed with the GATA-2/GFP vector, GATA-2/GFP-expressing stem cells failed to substantially contribute to the multilineage hematopoietic reconstitution of transplanted mice. Additionally, mice transplanted with purified, GATA-2/GFP-expressing cells showed post-transplant cytopenias and decreased numbers of total and gene-modified bone marrow Sca-1(+) Lin- cells. Although Sca-1(+) Lin- bone marrow cells expressing the GATA-2/GFP vector were detected after transplantation, no appreciable expansion in their numbers occurred. In contrast, control GFP-expressing Sca-1(+) Lin- cells expanded at least 40-fold after transplantation. Thus, enforced expression of GATA-2 in pluripotent hematopoietic cells blocked both their amplification and differentiation. There appears to be a critical dose-dependent effect of GATA-2 on blood cell differentiation in that downregulation of GATA-2 expression is necessary for stem cells to contribute to hematopoiesis in vivo.

In vivo selection of retrovirally transduced hematopoietic stem cells.

One of the main impediments to effective gene therapy of blood disorders is the resistance of human hematopoietic stem cells to stable genetic modification. We show here that a small minority of retrovirally transduced stem cells can be selectively enriched in vivo, which might be a way to circumvent this obstacle. We constructed two retroviral vectors containing an antifolate-resistant dihydrofolate reductase cDNA transcriptionally linked to a reporter gene. Mice were transplanted with transduced bone marrow cells and then treated with an antifolate-based regimen that kills unmodified stem cells. Drug treatment significantly increased the percentage of vector-expressing peripheral blood erythrocytes, platelets, granulocytes, and T and B lymphocytes. Secondary transplant experiments demonstrated that selection occurred at the level of hematopoietic stem cells. This system for in vivo stem-cell selection provides a means to increase the number of genetically modified cells after transplant, and may circumvent an substantial obstacle to successful gene therapy for human blood diseases.

Tumor lysis syndrome and acute renal failure after treatment of non-small-cell lung carcinoma with combination irinotecan and cisplatin.

Tumor lysis syndrome, characterized by multiple metabolic abnormalities resulting from abrupt tumor cell death and release of intracellular constituents and metabolites, is most commonly associated with the treatment of highly chemotherapy-sensitive lymphoid and leukemic neoplasms. The authors report a case of tumor lysis syndrome accompanied by acute renal failure that occurred in a patient with stage IV non-small-cell lung cancer who was treated with topoisomerase I inhibitor, irinotecan, and cisplatin. Consistent with the rapid tumor lysis, an objective, marked, early clinical response was observed. Attention to adequate hydration, electrolytes, and renal function should be given to outpatients with non-small-cell lung cancer who receive newer chemotherapeutic agents that have greater efficacy toward this group of tumors.

An improved method for generating retroviral producer clones for vectors lacking a selectable marker gene.

Most retroviral vectors used in preclinical and clinical studies contain a selectable marker gene to facilitate the generation of producer clones. However, the expression of such genes in target cells is often undesirable since this may modify cellular phenotype and invoke a host immune response. Unfortunately, the efficient identification of high-titer producer clones for vectors lacking a selectable marker gene continues to be problematic and lacking for a standard methodology. Despite recent improvements in the screening techniques for identifying high-titer producer clones without the aid of a selectable marker, a solution to the fundamental problem of the very low frequency occurrence of high-titer clones within the starting cell population has not emerged. We have developed a strategy which greatly increases the frequency of virus-producing clones, including those with high-titer, within the population of transduced cells to be screened. This approach relies on the use of high-titer vector preparations generated in 293T cells by co-transfection of retroviral packaging and vector plasmids. Viral preparations of a vector lacking a selectable marker were used to repeatedly transduce exponentially growing packaging cells at a high multiplicity of infection (MOI). Each cell in the resulting polyclonal population of producer cells contained multiple copies of the unrearranged vector genome. Greater than 95% of the clones derived from this population produced vector particles as judged by slot blot analysis of viral RNA from conditioned media. Numerous clones with estimated titers of 10(5)-10(6) were identified. These titers were confirmed using a standard vector genome transmission assay. This approach significantly enhances the ability, without large scale screening, to easily identify high-titer clones lacking a selectable marker and should facilitate the routine use of simplified gene marking and therapeutic vectors.

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.

Retroviral transduction of protein kinase C-gamma into cytotoxic T lymphocyte clones leads to immortalization with retention of specific function.

The molecular pathways that are responsible for delivering the proliferative signals from the cell surface to the nucleus in T lymphocytes are still unresolved, but recent data implicates protein kinase C (PKC) involvement in the TCR signaling pathway. To further address the role of PKC in T cell activation, the effects of high level expression of the PKC-gamma isoenzyme in murine CTL clones were examined. Unlike the parental cells that required periodic Ag stimulation for cell activation and growth, cells expressing a retrovirally transduced PKC-gamma gene propagated in culture independent of the need for Ag stimulation, although maintaining identical functional specificity to the parental CTL. Constitutive PKC-gamma expression may therefore mimic physiologic PKC activation, thereby abrogating the requirement for TCR-Ag interaction in T cell activation.

Protein kinase C gamma expression mimics phorbol ester-induced transcriptional activation of a murine VL30 enhancer element.

Protein kinase C (PKC), a critical component in the regulation of cell growth, is thought to participate in transmitting the signals of certain cell surface receptor activation events to the nucleus. We have previously shown that stable expression of the PKC gamma isoenzyme in NIH 3T3 cells causes altered growth and enhanced tumorigenicity. In this report, we show that transient expression of the PKC gamma isoenzyme can trans-activate a murine VL30 enhancer element in a pattern similar to that of the phorbol ester tumor promoter 12-O-tetradecanoylphorbol-13-acetate. In contrast, ras activation of this element is distinct both quantitatively and qualitatively from PKC gamma and 12-O-tetradecanoylphorbol-13-acetate activation. These results provide direct evidence that PKC is the cellular mediator in the activation of phorbol ester-responsive genes and suggest a mechanism by which abnormal PKC expression might lead to altered growth control by changing the pattern of cellular gene expression.

Increased expression of glycolysis-associated genes in oncogene-transformed and growth-accelerated states.

An accelerated rate of glucose transport and catabolism is a common characteristic of cellular transformation. We have previously found elevated expression of the glycolytic enzyme glyceraldehyde-3-phosphate dehydrogenase (GAPDH) in human pancreatic and colonic adenocarcinomas (Schek et al.: Cancer Res 48:6354-6359, 1988). To investigate further the expression of this enzyme in the process of tumorigenesis, we examined GAPDH expression in a panel of oncogene-transformed fibroblasts. Significant elevations of GAPDH mRNA and glucose transporter protein mRNA levels were observed in ras- and mos-transformed NIH 3T3 cells, whereas little or no change was found in c-src-, v-src-, c-myc-, E1A-, v-fos-, and PKC-gamma-transfected cells. Furthermore, the level of GAPDH mRNA correlated with the transformed state in a series of ras-transformed and revertant cell lines. Immunoblot analysis confirmed that GAPDH polypeptide was significantly elevated in the cell lines with elevated mRNA levels. Cell cycle analysis data suggested that the effect on GAPDH expression correlated with oncogene expression rather than cell growth fraction. These results suggest that altered GAPDH gene expression occurs during some growth deregulated states, and this, along with increased glucose transporter (and possibly other glycolytic enzyme) expression, is likely to contribute to the increased metabolic capacity of cells in these states.

Altered growth regulation and enhanced tumorigenicity of NIH 3T3 fibroblasts transfected with protein kinase C-I cDNA.

Transfection of NIH 3T3 cells with plasmids containing rat brain protein kinase C-I (PKC-I) cDNA controlled by strong viral promoter/enhancer elements led to PKC-I gene expression as assessed by Northern analysis, cellular binding of phorbol ester, immunoblotting of cellular PKC, and membrane-associated PKC activity. While transfection did not induce foci, altered growth regulation was observed in established transfectant lines: transfectants displayed reduced dependence on serum for growth, grew to higher saturation densities, and displayed enhanced tumorigenicity when inoculated into nude mice. Continued high-level expression of PKC-I, however, may not be obligatory for the malignant phenotype in vivo. Tumors that retained transfected sequences had lower PKC-I transcript levels than the parental in vitro lines, suggesting an in vivo modulation. Our data show that PKC-I dysregulation leads to altered cell growth regulation and may be functionally equivalent to the action of tumor promoters.