The potent enhancer activity of the polycythemic strain of spleen focus-forming virus in hematopoietic cells is governed by a binding site for Sp1 in the upstream control region and by a unique enhancer core motif, creating an exclusive target for PEBP/CBF

Human Lentiviral Gene Therapy Restores the Cellular Phenotype of Autosomal Recessive Complete IFN-γR1 Deficiency

Autosomal recessive (AR) complete interferon-γ receptor 1 (IFN-γR1) deficiency, also known as one genetic etiology of Mendelian susceptibility to mycobacterial disease (MSMD), is a life-threatening congenital disease leading to premature death. Affected patients present a pathognomonic predisposition to recurrent and severe infections with environmental mycobacteria or the Mycobacterium bovis bacillus Calmette-Guérin (BCG) vaccine. Current therapeutic options are limited to antibiotic treatment and hematopoietic stem cell transplantation, however with poor outcome. Given the clinical success of gene therapy, we introduce the first lentiviral-based gene therapy approach to restore expression and function of the human IFN-γR-downstream signaling cascade. In our study, we developed lentiviral vectors constitutively expressing the human IFN-γR1 and demonstrate stable transgene expression without interference with cell viability and proliferation in transduced human hematopoietic cells. Using an IFN-γR1-deficient HeLa cell model, we show stable receptor reconstitution and restored IFN-γR1 signaling without adverse effect on cell functionality. Transduction of both SV40-immortalized and primary fibroblasts derived from IFN-γR1-deficient MSMD patients was able to recover IFN-γR1 expression and restore type II IFN signaling upon stimulation with IFN-γ. In summary, we highlight lentiviral vectors to correct the IFN-γ mediated immunity and present the first gene therapy approach for patients suffering from AR complete IFN-γR1 deficiency.

In-vivo RGB marking and multicolour single-cell tracking in the adult brain

In neuroscience it is a technical challenge to identify and follow the temporal and spatial distribution of cells as they differentiate. We hypothesised that RGB marking, the tagging of individual cells with unique hues resulting from simultaneous expression of the three basic colours red, green and blue, provides a convenient toolbox for the study of the CNS anatomy at the single-cell level. Using γ-retroviral and lentiviral vector sets we describe for the first time the in-vivo multicolour RGB marking of neurons in the adult brain. RGB marking also enabled us to track the spatial and temporal fate of neural stem cells in the adult brain. The application of different viral envelopes and promoters provided a useful approach to track the generation of neurons vs. glial cells at the neurogenic niche, allowing the identification of the prominent generation of new astrocytes to the striatum. Multicolour RGB marking could serve as a universal and reproducible method to study and manipulate the CNS at the single-cell level, in both health and disease.

Temporal dynamics of hippocampal neurogenesis in chronic neurodegeneration

Increased neurogenesis has been reported in neurodegenerative disease, but its significance is unclear. In a mouse model of prion disease, Gomez-Nicola et al. detect increased neurogenesis in the dentate gyrus that partially counteracts neuronal loss. Targeting neurogenesis may have therapeutic potential.

The study of neurogenesis during chronic neurodegeneration is crucial in order to understand the intrinsic repair mechanisms of the brain, and key to designing therapeutic strategies. In this study, using an experimental model of progressive chronic neurodegeneration, murine prion disease, we define the temporal dynamics of the generation, maturation and integration of new neurons in the hippocampal dentate gyrus, using dual pulse-chase, multicolour γ-retroviral tracing, transmission electron microscopy and patch-clamp. We found increased neurogenesis during the progression of prion disease, which partially counteracts the effects of chronic neurodegeneration, as evidenced by blocking neurogenesis with cytosine arabinoside, and helps to preserve the hippocampal function. Evidence obtained from human post-mortem samples, of both variant Creutzfeldt-Jakob disease and Alzheimer’s disease patients, also suggests increased neurogenic activity. These results open a new avenue into the exploration of the effects and regulation of neurogenesis during chronic neurodegeneration, and offer a new model to reproduce the changes observed in human neurodegenerative diseases.

A ubiquitous chromatin opening element prevents transgene silencing in pluripotent stem cells and their differentiated progeny

Methylation-induced gene silencing represents a major obstacle to efficient transgene expression in pluripotent cells and thereof derived tissues. As ubiquitous chromatin opening elements (UCOE) have been shown to prevent transgene silencing in cell lines and primary hematopoietic cells, we hypothesized a similar activity in pluripotent cells. This concept was investigated in the context of cytidine deaminase (CDD) gene transfer, an approach to render hematopoietic cells resistant to the chemotherapeutic agent Ara-C. When murine induced pluripotent stem cells (iPSC)/embryonic stem cells (ESCs) were transduced with self-inactivating lentiviral vectors using housekeeping (truncated elongation factor 1α; EFS) or viral (spleen focus-forming virus; SFFV) promoters, incorporation of an heterogeneous nuclear ribonucleoproteins A2 B1/chromobox protein homolog 3 locus-derived UCOE (A2UCOE) significantly increased transgene expression and Ara-C resistance and effectively prevented silencing of the SFFV-promoter. The EFS promoter showed relatively stable transgene expression in naïve iPSCs, but rapid transgene silencing was observed upon hematopoietic differentiation. When combined with the A2UCOE, however, the EFS promoter yielded stable transgene expression in 73% ± 6% of CD41(+) hematopoietic progeny, markedly increased CDD expression levels, and significantly enhanced Ara-C resistance in clonogenic cells. Bisulfite sequencing revealed protection from differentiation-induced promoter CpG methylation to be associated with these effects. Similar transgene promoting activities of the A2UCOE were observed during murine neurogenic differentiation, in naïve human pluripotent cells, and during nondirected multilineage differentiation of these cells. Thus, our data provide strong evidence that UCOEs can efficiently prevent transgene silencing in iPS/ESCs and their differentiated progeny and thereby introduce a generalized concept to circumvent differentiation-induced transgene silencing during the generation of advanced iPSC/ESC-based gene and cell therapy products.

Insertion of myeloid-active elements into the human cytomegalovirus major immediate early promoter is not sufficient to drive its activation upon infection of undifferentiated myeloid cells

The Major Immediate Early Promoter (MIEP) of human cytomegalovirus (HCMV) controls viral Immediate Early (IE) gene expression, which must be activated to initiate productive infection and repressed to establish latency. Regulation of the MIEP is critical for both viral spread and persistence. In addition to the Daxx-mediated intrinsic cellular defense that regulates the MIEP, the cell-type specific balance between cellular activators and repressors of the promoter may help dictate whether viral IE genes will be expressed or silenced. For example, in undifferentiated myeloid cells, transcriptional repressors of the MIEP may outnumber transcriptional activators, leading to promoter silencing and latency establishment. We created a recombinant viral genome in which a myeloid-active promoter replaced part of the MIEP. The viable virus generated failed to express the viral IE genes in an undifferentiated myeloid cell line. These observations have mechanistic implications regarding how viral IE gene expression is regulated during latency.

Efficient hematopoietic redifferentiation of induced pluripotent stem cells derived from primitive murine bone marrow cells

Heterogeneity among induced pluripotent stem cell (iPSC) lines with regard to their gene expression profile and differentiation potential has been described and at least partly linked to the tissue of origin. Here, we generated iPSCs from primitive [lineage negative (Lin(neg))] and nonadherent differentiated [lineage positive (Lin(pos))] bone marrow cells (BM-iPSC), and compared their differentiation potential to that of fibroblast-derived iPSCs (Fib-iPSC) and embryonic stem cells (ESC). In the undifferentiated state, individual iPSC clones but also ESCs proved remarkably similar when analyzed for alkaline phosphatase and SSEA-1 staining, endogenous expression of the pluripotency genes Nanog, Oct4, and Sox2, or global gene expression profiles. However, substantial differences between iPSC clones were observed after induction of differentiation, which became most obvious upon cytokine-mediated instruction toward the hematopoietic lineage. All 3 BM-iPSC lines derived from undifferentiated Lin(neg) cells yielded high proportions of cells expressing the hematopoietic differentiation marker CD41 and in 2 of these lines high proportions of CD41+/ CD45+ cells were detected. In contrast, little hematopoiesis-specific surface marker expression was detected in 4 Lin(pos) BM-iPSC and 3 Fib-iPSC lines. These results were corroborated by functional studies demonstrating robust colony outgrowth from hematopoietic progenitors in 2 of the Lin(neg) BM-iPSCs only. Thus, in conclusion, our data demonstrate efficient generation of iPSCs from primitive hematopoietic tissue as well as efficient hematopoietic redifferentiation for Lin(neg) BM-iPSC lines, thereby supporting the notion of an epigenetic memory in iPSCs.

A ubiquitous chromatin opening element (UCOE) confers resistance to DNA methylation-mediated silencing of lentiviral vectors

DNA methylation may restrict the activity of gene transfer vectors due to inadvertent silencing. In P19 embryonic carcinoma cells in vitro, we found that transgene expression regulated by the SFFV LTR and EF1 alpha promoter declined rapidly within 16 days, but for A2UCOE derived from the human HNRPA2B1-CBX3 housekeeping gene locus, remained completely stable. Silencing correlated with extensive epigenetic methylation of CpG sites, whereas the A2UCOE was almost completely resistant. Linking of the A2UCOE upstream of the SFFV LTR protected this element from both DNA methylation and silencing. Analysis of engrafted hematopoietic cells in vivo transduced with the same vectors revealed a similar pattern. The A2UCOE displayed little or no methylation in either primary or secondary graft recipients, and gene expression profiles were highly conserved between the two groups. These studies provide convincing evidence that DNA methylation plays a direct role in regulating self-inactivating (SIN) lentiviral transgene expression, and that the stability of expression from the A2UCOE is, at least in part, due to methylation resistance. The A2UCOE therefore has considerable utility for gene therapy applications where reliable and sustained gene expression is desirable.

Correction of B-cell development in Btk-deficient mice using lentiviral vectors with codon-optimized human BTK

X-linked agammaglobulinemia (XLA) is the most common primary immunodeficiency (PID) in man and caused by mutations in the Bruton's tyrosine kinase (BTK) gene. XLA is characterized by a B-cell differentiation arrest in bone marrow, absence of mature B cells and immunoglobulins (Igs), and recurrent bacterial infections. We used self-inactivating lentiviral vectors expressing codon-optimized human BTK under the control of three different ubiquitous or B cell-specific promoters. Btk-/- mice engrafted with transduced cells showed correction of both precursor B-cell and peripheral B-cell development. Lentiviral vectors containing the wildtype BTK sequence did not correct the phenotype. All treated mice with codon-optimized BTK exhibited the recovery of B1 cells in the peritoneal cavity, and of serum IgM and IgG3 levels. Calcium mobilization responses upon B-cell receptor stimulation as well as in vivo responses to T cell-independent antigens were restored. Viral promoters overexpressing BTK >100-fold above normal resulted in erythro-myeloid proliferations independent of insertional mutagenesis. However, transplantation into secondary Btk-/- recipients using cellular promoters resulted in functional restoration of peripheral B cells and IgM levels, without any adverse effects. In conclusion, transduction of human BTK corrects B-cell development and antigen-specific antibody responses in Btk-/- mice, thus indicating the feasibility of lentiviral gene therapy for XLA, provided that BTK expression does not vastly exceed normal levels.

A protocol describing the genetic correction of somatic human cells and subsequent generation of iPS cells

The generation of patient-specific induced pluripotent stem cells (iPSCs) offers unprecedented opportunities for modeling and treating human disease. In combination with gene therapy, the iPSC technology can be used to generate disease-free progenitor cells of potential interest for autologous cell therapy. We explain a protocol for the reproducible generation of genetically corrected iPSCs starting from the skin biopsies of Fanconi anemia patients using retroviral transduction with OCT4, SOX2 and KLF4. Before reprogramming, the fibroblasts and/or keratinocytes of the patients are genetically corrected with lentiviruses expressing FANCA. The same approach may be used for other diseases susceptible to gene therapy correction. Genetically corrected, characterized lines of patient-specific iPSCs can be obtained in 4-5 months.

Insertional transformation of hematopoietic cells by self-inactivating lentiviral and gammaretroviral vectors

Gene transfer vectors may cause clonal imbalance and even malignant cell transformation by insertional upregulation of proto-oncogenes. Lentiviral vectors (LV) with their preferred integration in transcribed genes are considered less genotoxic than gammaretroviral vectors (GV) with their preference for integration next to transcriptional start sites and regulatory gene regions. Using a sensitive cell culture assay and a series of self-inactivating (SIN) vectors, we found that the lentiviral insertion pattern was approximately threefold less likely than the gammaretroviral to trigger transformation of primary hematopoietic cells. However, lentivirally induced mutants also showed robust replating, in line with the selection for common insertion sites (CIS) in the first intron of the Evi1 proto-oncogene. This potent proto-oncogene thus represents a CIS for both GV and LV, despite major differences in their integration mechanisms. Altering the vectors' enhancer-promoter elements had a greater effect on safety than the retroviral insertion pattern. Clinical grade LV expressing the Wiskott-Aldrich syndrome (WAS) protein under control of its own promoter had no transforming potential. Mechanistic studies support the conclusion that enhancer-mediated gene activation is the major cause for insertional transformation of hematopoietic cells, opening rational strategies for risk prevention.

The genotoxic potential of retroviral vectors is strongly modulated by vector design and integration site selection in a mouse model of HSC gene therapy

gamma-Retroviral vectors (gammaRVs), which are commonly used in gene therapy, can trigger oncogenesis by insertional mutagenesis. Here, we have dissected the contribution of vector design and viral integration site selection (ISS) to oncogenesis using an in vivo genotoxicity assay based on transplantation of vector-transduced tumor-prone mouse hematopoietic stem/progenitor cells. By swapping genetic elements between gammaRV and lentiviral vectors (LVs), we have demonstrated that transcriptionally active long terminal repeats (LTRs) are major determinants of genotoxicity even when reconstituted in LVs and that self-inactivating (SIN) LTRs enhance the safety of gammaRVs. By comparing the genotoxicity of vectors with matched active LTRs, we were able to determine that substantially greater LV integration loads are required to approach the same oncogenic risk as gammaRVs. This difference in facilitating oncogenesis is likely to be explained by the observed preferential targeting of cancer genes by gammaRVs. This integration-site bias was intrinsic to gammaRVs, as it was also observed for SIN gammaRVs that lacked genotoxicity in our model. Our findings strongly support the use of SIN viral vector platforms and show that ISS can substantially modulate genotoxicity.

Physiological promoters reduce the genotoxic risk of integrating gene vectors

The possible activation of cellular proto-oncogenes as a result of clonal transformation is a potential limitation in a therapeutic approach involving random integration of gene vectors. Given that enhancer promiscuity represents an important mechanism of insertional transformation, we assessed the enhancer activities of various cellular and retroviral promoters in transient transfection assays, and also in a novel experimental system designed to measure the activation of a minigene cassette contained in stably integrating retroviral vectors. Retroviral enhancer-promoters showed a significantly greater potential to activate neighboring promoters than did cellular promoters derived from human genes, elongation factor-1alpha (EF1alpha) and phosphoglycerate kinase (PGK). Self-inactivating (SIN) vector design reduced but did not abolish enhancer interactions. Using a recently established cell culture assay that detects insertional transformation by serial replating of primary hematopoietic cells, we found that SIN vectors containing the EF1alpha promoter greatly decrease the risk of insertional transformation. Despite integration of multiple copies per cell, activation of the crucial proto-oncogene Evi1 was not detectable when using SIN-EF1alpha vectors. On the basis of several quantitative indicators, the decrease in transforming activity was highly significant (more than tenfold, P < 0.01) when compared with similarly designed vectors containing a retroviral enhancer-promoter with or without a well-characterized genetic insulator core element. In this manner, the insertional biosafety of therapeutic gene vectors can be greatly enhanced and proactively evaluated in sensitive cell-based assays.

In vivo selection of transduced hematopoietic stem cells and little evidence of their conversion into hepatocytes in vivo

BACKGROUND/AIMS

FMEV-type retroviral vector provides high transgene expression in hepatocytes and hematopoietic stem cells (HSCs). Here, we examined whether these vectors could provide a sufficient drug-resistance gene expression in HSCs and whether transduced HSCs could differentiate into hepatocytes in vivo.

METHODS

The CD45(+)/Lin(-) cells were transduced in vitro by FMEV-type vectors containing human O(6)-methylguanine-DNA methyltransferase (MGMT)/reporter genes and transferred into recipient mice. After the treatment with temozolomide and O(6)-benzylguanine (TMZ/BG) in vivo, we analyzed the transgene expression in peripheral blood cells by flow-cytometry. Immunohistochemistry was performed on the liver slices in partial hepatectomized recipient mice.

RESULTS

After TMZ/BG treatment, transduced host cells were enriched in recipient mice. In the liver, we observed the efficient transgene expression in many small cells along sinusoids. However, only few large cells in hepatic lobules expressed albumin. They also expressed both a transgene and a recipient marker gene, suggesting the fusion of donor HSCs with recipient hepatocytes.

CONCLUSIONS

This vector expressed a drug-resistance gene in HSCs highly enough to protect them from the drugs. But, the conversion of HSCs into hepatocytes in vivo might be a rare event in this model.

γ-Glutamylcysteine Synthetase and L-Buthionine-(S,R)-Sulfoximine: A New Selection Strategy for Gene-Transduced Neural and Hematopoietic Stem/Progenitor Cells

In most experimental gene therapy protocols involving stem/progenitor cells, only a small fraction of cells, often therapeutically inadequate, can be transduced and made to express the therapeutic gene. A promising strategy for overcoming this problem is the use of a dominant selection marker, such as a drug resistance gene. In this paper, we explore the potential of the heavy subunit of gamma-glutamylcysteine synthetase (gamma-GCSh) to act as a selection marker. We found that 3T3 fibroblasts transduced with the bicistronic retroviral vector SF91/GCSh-eGFP, encoding gamma-GCSh and the enhanced green fluorescent protein (eGFP), were highly resistant to L-buthionine-(S,R)-sulfoximine (BSO), a gamma-GCS inhibitor with a low clinical toxicity profile. The level of resistance was not proportional to the increase in intracellular glutathione. In fact, cells overexpressing both heavy and light gamma-GCS subunits had higher intracellular GSH levels, and a lower level of resistance to the cytotoxic activity of BSO, compared with cells overexpressing gamma-GCSh alone. 3T3 fibroblasts overexpressing gamma-GCSh could be selected from cultures containing both naive and gene-modified cells by application of exogenous BSO selection pressure for 4 days. Also, primary neural stem/progenitor cells derived from the lateral ventricles of mouse neonatal brains and primary hematopoietic stem/progenitor cells (HSCs/HPCs) from mouse bone marrow, transduced with the gamma-GCSh-eGFP vector, could be selected by BSO treatment in vitro. On ex vivo BSO selection and reimplantation into a syngeneic myeloablated host, donor HSCs/HPCs repopulated the marrow and continued to express the transgene(s). These results provide proof of principle that somatic stem/progenitor cells, transduced simultaneously with a potentially curative gene and gamma-GCSh, can be selected by treatment with BSO before in vivo transplantation.

Self-inactivating retroviral vectors with improved RNA processing

Three RNA features have been identified that elevate retroviral transgene expression: an intron in the 5' untranslated region (5'UTR), the absence of aberrant translational start codons and the presence of the post-transcriptional regulatory element (PRE) of the woodchuck hepatitis virus in the 3'UTR. To include such elements into self-inactivating (SIN) vectors with potentially improved safety, we excised the strong retroviral promoter from the U3 region of the 3' long terminal repeat (LTR) and inserted it either downstream or upstream of the retroviral RNA packaging signal (Psi). The latter concept is new and allows the use of an intron in the 5'UTR, taking advantage of retroviral splice sites surrounding Psi. Three LTR and four SIN vectors were compared to address the impact of RNA elements on titer, splice regulation and transgene expression. Although titers of SIN vectors were about 20-fold lower than those of their LTR counterparts, inclusion of the PRE allowed production of more than 10(6) infectious units per ml without further vector optimizations. In comparison with state-of-the-art LTR vectors, the intron-containing SIN vectors showed greatly improved splicing. With regard to transgene expression, the intron-containing SIN vectors largely matched or even exceeded the LTR counterparts in all cell types investigated (embryonic carcinoma cells, fibroblasts, primary T cells and hematopoietic progenitor cells).

Efficient expansion and gene transduction of mouse neural stem/progenitor cells on recombinant fibronectin

Neural stem/progenitor cells (NSCs) are commonly grown as floating neurospheres in medium containing basic fibroblast growth factor and epidermal growth factor. Under these conditions, about 1% of the cells retain multipotentiality. We developed a protocol based on culture of NSCs in adherence on recombinant fibronectin (rFN) to transduce up to 90% NSCs at a multiplicity of infection of 2 with no need for viral concentration or production of serum-free retroviral supernatants. NSCs grew faster on rFN than as neurospheres on tissue culture plastic and did not lose their stem cell nature or multipotentiality. Furthermore, retroviral-mediated transgene expression was sustained with time in culture and upon differentiation into neurons and astrocytes. These experimental conditions may be utilized to study the function of various genes in NSCs, and to manipulate NSCs for gene and cell therapy of several neurological diseases.

Engineered long terminal repeats of retroviral vectors enhance transgene expression in hepatocytes in vitro and in vivo

To analyze the important elements for retroviral expression in hepatocytes, cis-acting elements in the U3 region of the long terminal repeat (LTR) of the polycythemic strain of spleen focus-forming virus (SFFVp) were analyzed in a hepatocellular carcinoma cell line. Two cis-acting elements located within the upstream region of the direct repeat, which positively regulated retroviral expression, were identified. Transcription factors NFAT5 and Sp1, which are ubiquitously expressed in a variety of tissues, bound to these elements. To increase specificity without lowering the potency of retroviral expression in hepatocytes, these elements were replaced by a sequence derived from the hepatitis B virus enhancer II region. Novel vectors, SF-Hep3 and SF-Hep5 (SFFVp-based vector for hepatocytes 3 and 5), were developed with these engineered LTRs. The engineered LTRs of these vectors enhanced the retroviral expression only in hepatocellular carcinoma cell lines in vitro. These vectors also increased transgene expression 4- to 9-fold or 3.5- to 5-fold in comparison with a Moloney murine leukemia virus-based vector or a vector containing the wild-type LTR of SFFVp, respectively, in murine hepatocytes in vivo.

Triple basepair changes within and adjacent to the conserved YY1 motif upstream of the U3 enhancer repeats of SL3-3 murine leukemia virus cause a small but significant shortening of latency of T-lymphoma induction

A highly conserved sequence upstream of the transcriptional enhancer in the U3 of murine leukemia viruses (MLVs) was reported to mediate negative regulation of their expression. In transient expression studies, negative regulation was reported to be conferred by coexpression of the transcription factor YY1, which binds to a motif in the upstream conserved region (UCR). To address the function of the UCR and its YY1-motif in an in vivo model of MLV-host interactions we introduced six consecutive triple basepair mutations into this region of the potent T-lymphomagenic SL3-3 MLV. We report that all mutants have retained their replication competence and that they all, like the SL3-3 wild type (wt), induce T-cell lymphomas when injected into newborn mice of the SWR strain. However, all mutants induced disease with slightly shorter latency periods than the wt SL3-3, suggesting that the YY1 motif as well as its immediate context in the UCR have a negative effect on the pathogenicity of the virus. This result may have implications for the design of retroviral vectors.

AML1-ETO inhibits maturation of multiple lymphohematopoietic lineages and induces myeloblast transformation in synergy with ICSBP deficiency

The translocation (8;21), generating the AML1-ETO fusion protein, is one of the most frequent chromosomal abnormalities associated with acute myelogenous leukemia (AML). To elucidate its role in oncogenesis, bone marrow (BM) cells were infected with a retroviral vector carrying AML1-ETO and transplanted into mice. In contrast to previous transgenic mouse models, we show that AML1-ETO directly stimulates granulopoiesis, suppresses erythropoiesis, and impairs the maturation of myeloid, B, and T lymphoid cells in vivo. To determine the significance of earlier findings that expression of the tumor suppressor ICSBP is often downregulated in AML myeloblasts, AML1-ETO was introduced into BM cells derived from mice lacking the interferon regulatory factor ICSBP. Our findings demonstrate that AML1-ETO synergizes with an ICSBP deficiency to induce myeloblastic transformation in the BM, reminiscent of AML.

Upstream conserved sequences of mouse leukemia viruses are important for high transgene expression in lymphoid and hematopoietic cells

Highly conserved enhancer sequences located in the upstream part of the long terminal repeat (LTR) of murine leukemia retroviruses (MLV) were reported to compromise viral gene expression in multipotent embryonic cells in vitro and to reduce the likelihood for maintenance of retroviral gene expression in hematopoietic cells in vivo. We show that deletion of these sequences (nucleotides +37 to +95) attenuates rather than increases the transcriptional activity of retroviral vectors in hematopoietic cells almost independently of the developmental lineage (erythroid, myeloid, or lymphoid). Expression rates of modified vectors were reduced by as much as 34-65%, although the strong enhancer array located in the direct repeat of the LTR was preserved. Sequence analysis and electrophoretic mobility shift assays revealed the presence of a highly conserved binding site for NFAT (nuclear factor of activated T cells) proteins that immediately neighbors a known binding site for the transcription factor Yin-Yang1 (YY1) [corrected]. Specific inactivation of the NFAT site reduced transgene expression in all cell types investigated and had a similar effect as the destruction of a neighboring SP1 motif. Combined destruction of individual motifs for NFAT, SP1, and E twenty-six transcription factors (ETS) resulted in a severe attenuation (by 40-60%) of the retroviral enhancer. These results provide novel clues for the manipulation of retrovirus replication and vector tropism.

High-level transduction and gene expression in hematopoietic repopulating cells using a human immunodeficiency [correction of imunodeficiency] virus type 1-based lentiviral vector containing an internal spleen focus forming virus promoter

Prolonged exposure of human hematopoietic stem cells (HSC) to growth factors for efficient transduction by murine oncoretroviral vectors has major detrimental effects on repopulating activity. In this study, we have used a vesicular stomatitis virus G envelope protein (VSV-G)-pseudotyped human immunodeficiency virus type 1 (HIV-1) lentiviral-based vector system to transduce cord blood (CB) CD34+ cells over a limited time period (< or =24 hours). Under these conditions, significant gene marking was observed in engrafted human lymphoid, myeloid, and progenitor cells in all transplanted Severe Combined Immunodeficient (SCID) mice. To enhance the level of gene expression in hematopoietic cells, we also generated a series of lentiviral vectors incorporating the spleen focus forming virus (SFFV) long terminal repeat (LTR) sequences, and the Woodchuck hepatitis virus posttranscriptional regulatory element (WPRE). By including the central polypurine tract (cPPT) sequence of HIV-1 we were then able to achieve high levels of transduction (over 80%) and gene expression in vivo after a single exposure to viral supernatant. These results demonstrate that lentiviral vectors are highly effective for gene transfer to human HSC, and that SFFV regulatory sequences can be successfully incorporated to enhance the long-term expression of a transgene in primary human hematopoietic cells in vivo.

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.

High expression of transgenes mediated by hybrid retroviral vectors in hepatocytes: comparison of promoters from murine retroviruses in vitro and in vivo

To achieve high transgene expression in the liver, we have compared the reporter gene expression among various murine retroviral long terminal repeats (LTRs) or leader sequences in vitro. Transient reporter gene expression assays revealed the highest gene expression by the polycythemic strain of spleen focus-forming virus (SFFVp) LTR in differentiated hepatocellular carcinoma cell lines, HuH-7 and PLC/PRF/5. However, remarkable difference was not observed among LTRs in other types of human liver tumor cell lines. Essentially the same results were obtained by infecting these cells with a series of retroviral vectors. Repression of transgene expression was observed by the leader sequences from Moloney murine leukemia virus (MoMLV), but not from mouse embryonic stem cell virus (MESV). Strengths of the promoters were further compared in murine hepatocytes in vivo. Although the proportions of genomic integration were almost the same, higher gene expression was observed by the FMEV-type vector, which contained the SFFVp LTR and the MESV leader, in comparison with that by the MoMLV-based vector. Thus, FMEV-type vectors may represent a novel type of vectors for human gene therapy with hepatocytes.

In vivo analysis of retroviral enhancer mutations in hematopoietic cells: SP1/EGR1 and ETS/GATA motifs contribute to long terminal repeat specificity

The objective of this work was to identify, in the context of chromosomally integrated DNA, the contribution of defined transcription factor binding motifs to the function of a complex retrovirus enhancer in hematopoietic cells in vivo. Repopulating murine hematopoietic cells were transduced with equal gene dosages of replication-incompetent retrovirus vectors encoding enhanced green fluorescent protein. Enhancer sequences were derived from mouse spleen focus-forming virus. Destruction of GC-rich sites representing overlapping targets for SP1 or EGR1 uniformly attenuated gene expression (approximately 25 to 70% of wild-type levels) in all hematopoietic lineages, as shown by multicolor flow cytometry of peripheral blood and bone marrow cells at various time points posttransplantation. In contrast, a point mutation within a dual ETS/GATA motif that abolished transactivation by ETS factors but not by GATA-1 slightly increased activity in erythroid cells and significantly attenuated enhancer function in T lymphocytes. This study shows that controlled gene transfer in transplantable hematopoietic cells allows a functional analysis of distinct cis elements within a complex retrovirus enhancer, as required for the characterization and engineering of various cellular and viral regulatory sequences in basic research and gene therapy.

Influence of multiplicity of infection and protein stability on retroviral vector-mediated gene expression in hematopoietic cells

Using retroviral vectors encoding enhanced green fluorescent protein (EGFP), we addressed to what extent expression of retroviral transgenes in hematopoietic cells depends on the multiplicity of infection (MOI) and on the half-life of the encoded protein. We show that an elevation of the MOI not only elevates the frequency of transduced cells, but also increases transgene expression levels and reduces interanimal variability in vivo (hematopoietic cells of C57BL/6J mice analyzed 13 weeks after transplantation). This suggests that the MOI has to be carefully controlled and should be adapted as desired for clinical studies when evaluating vector performance in preclinical models. The impact of protein stability is demonstrated by comparing vectors expressing EGFP or a destabilized variant with a C-terminal PEST-sequence, d2EGFP. The loss of expression with d2EGFP was more pronounced in terminally differentiated cells of the peripheral blood (>30 fold) than in progenitor cells (five- to 10-fold), indicating a stronger transcription of the retroviral promoter in progenitor cells and a predominant role of protein inheritance over de novo synthesis of transgenic protein in mature blood cells. This analysis reveals an important and differentiation-dependent contribution of protein half-life to the expression of retroviral vectors in hematopoietic cells, establishes d2EGFP as a more accurate reporter for determination of vector transcription, and also suggests that preclinical data obtained under conditions of high transduction rates or with vectors expressing stable reporter proteins require careful interpretation.

Progress in the use of gene transfer methods to treat genetic blood diseases

A report by French physician-scientists suggests a successful application of gene transfer methods in the treatment of two children with severe combined immunodeficiency (SCID) due to defective interleukin 2 receptor common gamma chain. The protocol used in this clinical trial was derived from a number of preclinical and basic studies leading to improved transduction of hematopoietic stem and primitive progenitor cells using retrovirus vectors. These improvements have also been shown to impact transduction of a long-lived progenitor cell in a chemotherapy protocol in cancer patients. The improved results of these human trials come during a period of increased scrutiny and criticism of human gene therapy trials, due, in part, to significant toxicities in some trials using adenovirus-based vectors. The potential efficacy versus toxicity of phase I trials of human gene therapy is also under question. After many years of research, however, there appears to be real evidence that genetic diseases may be successfully treated by gene transfer techniques. Future clinical studies should be based on continued progress in the understanding of the toxicology of gene delivery systems, vector technology, and target cell manipulation.

Efficient intracellular retrotransposition of an exogenous primate retrovirus genome

The foamy virus (FV) subgroup of Retroviridae reverse transcribe their RNA (pre-)genome late in the replication cycle before leaving an infected cell. We studied whether a marker gene-transducing FV vector is able to shuttle to the nucleus and integrate into host cell genomic DNA. While a potential intracellular retrotransposition of vectors derived from other retroviruses was below the detection limit of our assay, we found that up to 5% of cells transfected with the FV vector were stably transduced, harboring 1 to approximately 10 vector integrants. Generation of the integrants depended on expression of functional capsid, reverse transcriptase and integrase proteins, and did not involve an extracellular step. PCR analysis of the U3 region of the 5' long terminal repeat and determination of proviral integration sites showed that a reverse transcription step had taken place to generate the integrants. Co-expression of a mutated envelope allowing particle egress and avoiding extracellular infection resulted in a significantly increased rescue of cells harboring integrants, suggesting that accumulation of proviruses via intracellular retrotransposition represents an integral part of the FV replication strategy.

Complex effects of deletions in the 5' untranslated region of primate foamy virus on viral gene expression and RNA packaging

Due to various advantageous features there is current interest in retroviral vectors derived from primate foamy viruses (PFVs). Two PFV cis-acting sequences have been mapped in the 5' region of the RNA (pre-)genome and in the 3' pol genomic region. In order to genetically separate PFV packaging constructs from vector constructs, we investigated the effect of deletions in the 5' untranslated region (UTR) of PFV packaging constructs and vectors on gene expression and RNA incorporation into viral particles. Our results indicate that the 5' UTR serves different previously unknown functions. First, the R region of the long terminal repeat was found to be required for PFV gag gene expression. This regulation of gene expression appeared to be mainly posttranscriptional. Second, constructs with sequence deletions between the R region and the gag gene start codon packaged as much viral mRNA into particles as the undeleted construct, and RNA from such a 5'-UTR-deleted packaging construct was copackaged into vector-virus particles, together with vector RNA which was preferentially packaged. Finally, in the U5 region a sequence was identified that was required to allow cleavage of the Gag precursor protein by the pol gene-encoded protease, suggesting a role of RNA in PFV particle formation. Taken together, the results indicate that complex interactions of the viral RNA, capsid, and polymerase proteins take place during PFV particle formation and that a clear separation of PFV vector and packaging construct sequences may be difficult to achieve.

Retroviral vector-mediated gene expression in human CD34+CD38- cells expanded in vitro: cis elements of FMEV are superior to those of Mo-MuLV

A novel murine stromal cell line, HESS-M28, was established, which supports the expansion of human CD34+CD38- cells more than 300-fold in vitro in the presence of human IL-3 and SCF. These cells were used in an attempt to evaluate cis-acting elements of retroviral vectors in human primitive hematopoietic cells. Cord blood cells were cultured on top of the mixed cell layers of the stromal cell line, HESS-M28, and retroviral vector-producing cells. The FMEV-type vector SF/Lyt contained the spleen focus-forming virus U3 and the MESV primer-binding site (PBS), while MO3/Lyt contained the U3 region and PBS from Mo-MuLV. After transduction by the FMEV-type and Mo-MuLV-based vectors, expression of the marker gene murine CD8 (mCD8) was examined in CD34-, CD34+, and CD34+CD38- cells. In CD34+ and CD34+CD38- cells, expression of mCD8 was higher with the FMEV-type vector, SF/Lyt, compared with the cells transduced by the Mo-MuLV-based vector MO3/Lyt, although the expression was comparable in CD34- cells. Expression of marker genes was also confirmed in long-term culture-initiating cells (LTC-ICs) and SCID-repopulating cells (SRCs).

Variegation of retroviral vector gene expression in myeloid cells

We have comparatively evaluated the efficiency of a series of retroviral vectors transducing the gp91-phox gene, whose defects are responsible for impaired production of superoxide anion (O2-) by phagocytic cells and lead to the X-linked form of chronic granulomatous disease (X-CGD). These vectors included four constructs based on the MoMuLV backbone and expressing gp91-phox from the viral long terminal repeat (LTR) or from internal promoters, and one construct based on the myelotropic FMEV vector. Expression of the therapeutic gene from the MoMuLV LTR was unsatisfactory after transduction of the PLB985 X-CGD knockout cell line and of primary CD34+ hematopoietic progenitors from X-CGD patients. The presence of either constitutive or inducible internal promoters did not result in important improvements in the efficiency of O2- production and lowered the titers of the viral preparations. In contrast, sustained levels of superoxide generation were obtained upon transduction with the FMEV vector. To analyze the efficiency of transgene expression at the single cell level, over 150 cellular clones were generated from bulk cultures of PLB985 X-CGD cells transduced with this vector, each one representative of an individual transduction event. These clones revealed a markedly heterogeneous pattern of gp91-phox expression, ranging from complete silencing to full restoration of superoxide production. Within each clone, expression of the therapeutic gene correlated with the number of expressing cells rather than with the average levels of expression from each cell, indicating that at the single cell level, the proviral promoter is regulated by a binary, on/off mechanism. Moreover, both transduced bulk and clonal cell populations displayed a tendency to a progressive extinction of expression over time, with a mechanism involving LTR methylation. The design of novel retroviral vectors escaping silencing is highly desirable for efficient gene therapy.

Gene Therapy 2000

This article reviews 1) the use of gene transfer methods to genetically manipulate hematopoietic stem cell targets, 2) recent advances in technology that are addressing problems that have prevented widespread successful translation of gene transfer approaches for the cure of disease, and 3) recent regulatory issues related to human gene therapy trials.

In Section I, Dr. Nienhuis describes the use of alternative viral envelopes and vector systems to improve efficiency of transduction of hematopoietic stem cells. Major limitations of stem cell transduction are related to low levels of viral receptors on the stem cells of large animal species and the low frequency of cycling stem cells in the bone marrow. Attempts to circumvent these limitations by exploiting non-oncoretroviral vectors and pseudotyping of Moloney vectors with alternative envelopes are discussed.

In Section II, Dr. Hawley addresses new strategies to improve the expression of transgenes in cells derived from long-term reconstituting hematopoietic stem cells. Transgene silencing in transduced hematopoietic stem cells remains an obstacle to gene therapy for some gene sequences. New generations of retroviral backbones designed to both improve expression and reduce silencing in primary cells are explored.

In Section III, Drs. Smith and Cornetta update regulatory issues related to human gene therapy trials. Increased scrutiny of human trials has led to changes in requirements and shifts in emphasis of existing regulations, which apply to human gene therapy trials. The current Food and Drug Administration's structure and regulations and the roles of the Recombinant DNA Advisory Committee of the NIH and other sponsors and partners in gene therapy trials are reviewed.

Gene Therapy 2000

This article reviews 1) the use of gene transfer methods to genetically manipulate hematopoietic stem cell targets, 2) recent advances in technology that are addressing problems that have prevented widespread successful translation of gene transfer approaches for the cure of disease, and 3) recent regulatory issues related to human gene therapy trials.

In Section I, Dr. Nienhuis describes the use of alternative viral envelopes and vector systems to improve efficiency of transduction of hematopoietic stem cells. Major limitations of stem cell transduction are related to low levels of viral receptors on the stem cells of large animal species and the low frequency of cycling stem cells in the bone marrow. Attempts to circumvent these limitations by exploiting non-oncoretroviral vectors and pseudotyping of Moloney vectors with alternative envelopes are discussed.

In Section II, Dr. Hawley addresses new strategies to improve the expression of transgenes in cells derived from long-term reconstituting hematopoietic stem cells. Transgene silencing in transduced hematopoietic stem cells remains an obstacle to gene therapy for some gene sequences. New generations of retroviral backbones designed to both improve expression and reduce silencing in primary cells are explored.

In Section III, Drs. Smith and Cornetta update regulatory issues related to human gene therapy trials. Increased scrutiny of human trials has led to changes in requirements and shifts in emphasis of existing regulations, which apply to human gene therapy trials. The current Food and Drug Administration's structure and regulations and the roles of the Recombinant DNA Advisory Committee of the NIH and other sponsors and partners in gene therapy trials are reviewed.

Costimulation of transduced T lymphocytes via T cell receptor-CD3 complex and CD28 leads to increased transcription of integrated retrovirus

Primary human T lymphocytes were transduced at high efficiency with the Moloney murine leukemia virus (Mo-MuLV) vector, LNC-mB7-1, in which an internal cytomegalovirus (CMV) promoter drives expression of the murine B7-1 cDNA. Compared with transduced T cells expanded in IL-2 or reactivated with soluble antibodies to CD3 or CD28, transgene expression was significantly increased after activation on immobilized anti-CD3 antibodies (CD3i) or by simultaneous activation on immobilized anti-CD3 and anti-CD28 antibodies (CD3i/CD28i). A similar pattern of transgene expression was observed in T cells transduced with Mo-MuLV LNC-EGFP. Proviral copy number was maintained in LNC-mB7-1-transduced T cells expanded in IL-2 or reactivated on CD3i/CD28i. Substantial increases in LNC-mB7-1 steady state mRNA in reactivated T lymphocytes, compared with those maintained in IL-2, correlated with increased transcription of the LNC-mB7-1 proviral DNA. Furthermore, T cells transduced with the Mo-MuLV ZIPPGK-mADA, in which the mADA cDNA is driven by an internal human phosphoglycerate kinase (PGK) promoter, showed increases in steady state ZIPPGK-mADA RNA on reactivation. High levels of transgene expression were evident irrespective of cell cycle position in both CD4+ and CD8+ lymphocytes. After reactivation, increases in LNC-mB7-1 mRNA were observed in the presence of the protein synthesis inhibitor cycloheximide, indicating that proteins involved in upregulating transgene expression preexisted in transduced lymphocytes. Induction of transgene expression on CD3i/CD28i showed a dose-dependent decrease in transgene expression when incubated with selective protein kinase inhibitors. These data provide new insights into the mechanisms governing transgene expression driven by Mo-MuLV constructs containing internal promoters in transduced primary T lymphocytes.

Efficient gene transfer by hybrid retroviral vectors to murine spermatogenic cells

Using murine spermatogenic cell lines GC-1 spg and GC-2 spd(ts) as target cells, an attempt was made to design a retroviral vector that would transduce genes efficiently. Promoter activities of various retroviral long terminal repeats (LTRs) were examined by using chloramphenicol acetyltransferase (CAT) as a reporter. The U3 region of spleen focus-forming virus (SFFVp) showed higher enhancer activity than that of Moloney murine leukemia virus (Mo-MuLV) in both cell lines. The U3 region of myeloproliferative sarcoma virus (MPSV) showed higher activity only in GC-1 spg cells. Expression was suppressed by the repressor element of the primer-binding site (PBS) of the Moloney-related virus. The efficiency of transduction of the multidrug-resistance gene (mdr-1) by an Mo-MuLV-based vector was compared with hybrid vectors consisting of the murine embryonic stem cell virus (MESV) PBS and the LTR of either SFFVp or MPSV. Rhodamine efflux assays and colchicine-resistant colony-forming assays demonstrated higher gene expression by the hybrid vectors. Amphotropic and ecotropic receptors were found to be expressed and functional in both cell lines. Thus, these hybrid vectors represent a powerful tool by which to transfer genes into spermatogenic cells.

Design of 5' untranslated sequences in retroviral vectors developed for medical use

Utilizing genetic modules of simple retroviruses, we have developed a novel generation of gene transfer vectors with improved therapeutic potential. In the 5' untranslated "leader" sequences, all AUG codons which may aberrantly initiate translation and all viral coding sequences were removed. Thus, the probability of expressing unwanted peptides and the potential for homologous recombination with retroviral genes were largely reduced, and the cloning capacity was increased. The transgene was inserted to replace the viral gag sequences, and a new minimal splice acceptor was introduced, resulting in increased expression with all genes tested (those coding for human multidrug resistance 1 and enhanced green fluorescent protein, as well as the lacZ gene). These vectors may represent attractive tools for human gene therapy, because they increase the efficiency of transgene expression and may also increase safety in medical applications.

An enhancer located between the neutrophil elastase and proteinase 3 promoters is activated by Sp1 and an Ets factor

The adjacent neutrophil elastase, proteinase 3, and azurocidin genes encode serine proteases expressed specifically in immature myeloid cells. Subclones of a 17-kilobase (kb) murine neutrophil elastase genomic clone were assessed for their ability to stimulate the neutrophil elastase promoter in 32D cl3 myeloid cells. Region -9.3 to -7.3 kb stimulated transcription 7-fold, whereas other genomic segments were inactive. This enhancer is located in the second intron of the proteinase-3 gene and so may regulate more than one gene in the myeloid protease cluster. Deletional analysis of the enhancer identified several segments which activated the neutrophil elastase and thymidine kinase promoters 3-6-fold. The most active segment was a 220-base pair region centered at -8.6 kb, which activated transcription 31-fold. This segment contains an Sp1 consensus site, which bound Sp1, flanked by two Ets family consensus sequences, which bound PU.1, GABP, and an Ets factor present in myeloid cell extracts. Mutation of the Sp1-binding site reduced enhancer activity 8-fold in 32D cl3 cells, and mutation of either or both Ets-binding sites reduced activity 3-4-fold. Sp1 activated the distal enhancer 5-fold, GABP 3-fold, and the combination 8-fold in Schneider cells.

Generation of retroviral vector for clinical studies using transient transfection

Transient transfection of 293T cells was utilized to produce high-titer murine recombinant retroviral vectors for clinical studies. This system was initially optimized by gene transfer using different retroviral envelope proteins into activated human CD4+ T lymphocytes in vitro. Higher titer and infectivity were obtained than with stable murine producer lines; titers of 0.3-1 x 10(7) infectious units per milliliter for vectors encoding the green fluorescent protein (GFP) were achieved. Virions pseudotyped with envelope proteins from gibbon ape leukemia virus or amphotropic murine leukemia virus resulted in gene transfer of > or = 50% in CD4+ human T lymphocytes with this marker. Gene transfer of Rev M10 with this vector conferred resistance to HIV infection compared with negative controls in the absence of drug selection. Thus, the efficiency of transduction achieved under these conditions obviated the need to include selection to detect biologic effects in T cells. Finally, a protocol for the production of large-scale supernatants using transient transfection was optimized up to titers of 1.9 x 10(7) IU/ml. These packaging cells can be used to generate high-titer virus in sufficient quantities for clinical studies and will facilitate the rapid, cost-effective generation of improved retroviral, lentiviral, or other viral vectors for human gene therapy.

Cells expressing the human foamy virus (HFV) accessory Bet protein are resistant to productive HFV superinfection

Bet is a foamy virus (FV) accessory protein not required for virus replication. The function of Bet is not understood. We report on the generation of cell lines stably expressing the HFV Bet protein. In Bet+ cells, HFV replication was reduced by approximately 3-4 orders of magnitude compared with control cells. The HFV Bet-expressing cells only partially resisted infection by the distantly related feline FV (FFV). Pseudotyping experiments, using murine retroviral vectors with an HFV envelope, revealed that the resistance was not due to downregulation of the unknown HFV receptor. In transfection experiments, using proviral reporter gene constructs and infectious proviruses, no significant differences were detected between Bet+ and control cells. In infection experiments, HFV vectors expressing an indicator gene under control of the HFV promoters showed no activity in Bet+ cells. The results are best compatible with the hypothesis that the main block to productive superinfection of Bet+ cells occurs at an early stage of replication between virus entry and provirus establishment. We suggest that inhibition of provirus integration by Bet protein may serve a distinct function in the unique foamy virus replication cycle.

Characterization of a cis-acting sequence in the Pol region required to transfer human foamy virus vectors

To identify cis-acting elements in the foamy virus (FV) RNA pregenome, we developed a transient-vector-production system based on cotransfection of indicator gene-bearing vector and gag-pol and env expression plasmids. Two elements which were critical for vector transfer were found and mapped approximately. The first element was located in the RU5 leader and the 5' gag region (approximately up to position 650 of the viral RNA). The second element was located in an approximately 2-kb sequence in the 3' pol region. Although small 5' and 3' deletions, as well as internal deletions of the latter element, were tolerated, both elements were found to be absolutely required for vector transfer. The functional characterization of the pol region-located cis-acting element revealed that it is essential for efficient incorporation or the stability of particle-associated virion RNA. Furthermore, virions derived from a vector lacking this sequence were found to be deficient in the cleavage of the Gag protein by the Pol precursor protease. Our results suggest that during the formation of infectious virions, complex interactions between FV Gag and Pol and the viral RNA take place.

Host cis-mediated extinction of a retrovirus permissive for expression in embryonal stem cells during differentiation

The use of retroviral vectors for gene transfer into animals has been severely hampered by the lack of provirus transcription in the early embryo and embryonic stem (ES) cells. This primary block in provirus expression is maintained in differentiated cells by a cis-acting mechanism that is not well characterized. Retroviral vectors based on the murine embryonal stem cell virus (MESV), which overcome the transcriptional block in ES cells, were constructed to investigate this secondary mechanism. These vectors transferred G418 resistance to ES cells with the same efficiency as to fibroblasts, but overall transcript levels were greatly reduced. A mosaic but stable expression pattern was observed when single cells from G418-resistant clones were replated in G418 or assayed for expression of LacZ or interleukin-3. The expression levels in independent clones were variable and correlated inversely with methylation. However, a second, more pronounced, block to transcription was found upon differentiation induction. Differentiation of the infected ES cells to cells permissive for retroviral expression resulted in repression and complete extinction of provirus expression. Extinction was not accompanied by increased levels of methylation. Provirus expression is thus regulated by two independent cis-acting mechanisms: (i) partial repression in the undifferentiated state, accompanied by increased methylation but compatible with long-term, low expression of retroviral genes, and (ii) total repression and extinction during early stages of differentiation, apparently independent of changes in methylation. These results indicate a time window early during the transition from an undifferentiated to a differentiated stage in which provirus expression is silenced. The mechanisms are presently unknown, but elucidation of these events will have an important impact on vector development for targeting stem cells and for gene therapy.

Gene transfer into haemopoietic cells

The therapeutic potential achievable by efficient transfer and expression of genes into haemopoietic stem cells (HSC) is enormous. In addition to inherited disorders such as haemoglobinopathies and lysosomal storage disorders, this technology can be applied to acquired disorders such as myelosuppression induced by anticancer chemotherapy or infection with human immunodeficiency virus (HIV). To date retroviral vectors are the most attractive modality for gene transfer into HSC. Unfortunately, the expectations of gene therapy are more advanced than the methodology needed to fulfil the goals. In this chapter, the current concepts and limitations in the genetic manipulation of haemopoietic cells are presented. Overcoming these limitations requires not only improvement in isolation and expansion of HSC that contribute to long-term repopulation, but also development of better retroviral transfer systems. Current restrictions occur at various levels in the viral transfer process, including efficient cell entry, regulated expression levels, and sustained expression. The analysis of retroviral mutants has proven to be a successful approach to developing effective retroviral vectors for HSC gene therapy.