Lentivirus vectors incorporating the immunoglobulin heavy chain enhancer and matrix attachment regions provide position-independent expression in B lymphocytes

A major isoform of the E3 ubiquitin ligase March-I in antigen-presenting cells has regulatory sequences within its gene

Regulation of major histocompatibility complex class II (MHC-II) expression is important not only to maintain a diverse pool of MHC-II-peptide complexes but also to prevent development of autoimmunity. The membrane-associated RING-CH (March) E3 ubiquitin ligase March-I regulates ubiquitination and turnover of MHC-II-peptide complexes in resting dendritic cells (DCs) and B cells. However, activation of either cell type terminates March-I expression, thereby stabilizing MHC-II-peptide complexes. Despite March-I's important role in the biology of antigen-presenting cells (APCs), how expression of March-I mRNA is regulated remains unknown. We now show that both DCs and B cells possess a distinct isoform of March-I whose expression is regulated by a promoter located within the March-I gene. Using March-I promoter fragments to drive expression of GFP, we also identified a core promoter for expression of March-I in DCs and B cells, but not in fibroblasts, kidney cells, or epithelial cells, that contains regulatory regions that down-regulate March-I expression upon activation of DCs. Curiously, we found downstream sequence elements, present in the first coding exon of March-I in APCs, that confer regulation of March-I expression in activated APCs. In summary, our study identifies regulatory regions of the March-I gene that confer APC-specific expression and activation-induced modulation of March-I expression in DCs and B cells.

Generation of plasmid vectors expressing FLAG-tagged proteins under the regulation of human elongation factor-1α promoter using Gibson assembly

Gibson assembly (GA) cloning offers a rapid, reliable, and flexible alternative to conventional DNA cloning methods. We used GA to create customized plasmids for expression of exogenous genes in mouse embryonic stem cells (mESCs). Expression of exogenous genes under the control of the SV40 or human cytomegalovirus promoters diminishes quickly after transfection into mESCs. A remedy for this diminished expression is to use the human elongation factor-1 alpha (hEF1α) promoter to drive gene expression. Plasmid vectors containing hEF1α are not as widely available as SV40- or CMV-containing plasmids, especially those also containing N-terminal 3xFLAG-tags. The protocol described here is a rapid method to create plasmids expressing FLAG-tagged CstF-64 and CstF-64 mutant under the expressional regulation of the hEF1α promoter. GA uses a blend of DNA exonuclease, DNA polymerase and DNA ligase to make cloning of overlapping ends of DNA fragments possible. Based on the template DNAs we had available, we designed our constructs to be assembled into a single sequence. Our design used four DNA fragments: pcDNA 3.1 vector backbone, hEF1α promoter part 1, hEF1α promoter part 2 (which contained 3xFLAG-tag purchased as a double-stranded synthetic DNA fragment), and either CstF-64 or specific CstF-64 mutant. The sequences of these fragments were uploaded to a primer generation tool to design appropriate PCR primers for generating the DNA fragments. After PCR, DNA fragments were mixed with the vector containing the selective marker and the GA cloning reaction was assembled. Plasmids from individual transformed bacterial colonies were isolated. Initial screen of the plasmids was done by restriction digestion, followed by sequencing. In conclusion, GA allowed us to create customized plasmids for gene expression in 5 days, including construct screens and verification.

Gene delivery in malignant B cells using the combination of lentiviruses conjugated to anti-transferrin receptor antibodies and an immunoglobulin promoter

BACKGROUND

We previously developed an antibody-avidin fusion protein (ch128.1Av) specific for the human transferrin receptor 1 (TfR1; CD71) to be used as a delivery vector for cancer therapy and showed that ch128.1Av delivers the biotinylated plant toxin saporin-6 into malignant B cells. However, as a result of widespread expression of TfR1, delivery of the toxin to normal cells is a concern. Therefore, we explored the potential of a dual targeted lentiviral-mediated gene therapy strategy to restrict gene expression to malignant B cells. Targeting occurs through the use of ch128.1Av or its parental antibody without avidin (ch128.1) and through transcriptional regulation using an immunoglobulin promoter.

METHODS

Flow cytometry was used to detect the expression of enhanced green fluorescent protein (EGFP) in a panel of cell lines. Cell viability after specific delivery of the therapeutic gene FCU1, a chimeric enzyme consisting of cytosine deaminase genetically fused to uracil phosphoribosyltransferse that converts the 5-fluorocytosine (5-FC) prodrug into toxic metabolites, was monitored using the MTS or WST-1 viability assay.

RESULTS

We found that EGFP was specifically expressed in a panel of human malignant B-cell lines, but not in human malignant T-cell lines. EGFP expression was observed in all cell lines when a ubiquitous promoter was used. Furthermore, we show the decrease of cell viability in malignant plasma cells in the presence of 5-FC and the FCU1 gene.

CONCLUSIONS

The present study demonstrates that gene expression can be restricted to malignant B cells and suggests that this dual targeted gene therapy strategy may help to circumvent the potential side effects of certain TfR1-targeted protein delivery approaches.

Induced overexpression of OCT4A in human embryonic stem cells increases cloning efficiency

Our knowledge of the molecular mechanisms underlying human embryonic stem cell (hESC) self-renewal and differentiation is incomplete. The level of octamer-binding transcription factor 4 (Oct4), a critical regulator of pluripotency, is precisely controlled in mouse embryonic stem cells. However, studies of human OCT4 are often confounded by the presence of three isoforms and six expressed pseudogenes, which has complicated the interpretation of results. Using an inducible lentiviral overexpression and knockdown system to manipulate OCT4A above or below physiological levels, we specifically examine the functional role of the OCT4A isoform in hESC. (We also designed and generated a comparable series of vectors, which were not functional, for the overexpression and knockdown of OCT4B.) We show that specific knockdown of OCT4A results in hESC differentiation, as indicated by morphology changes, cell surface antigen expression, and upregulation of ectodermal genes. In contrast, inducible overexpression of OCT4A in hESC leads to a transient instability of the hESC phenotype, as indicated by changes in morphology, cell surface antigen expression, and transcriptional profile, that returns to baseline within 5 days. Interestingly, sustained expression of OCT4A past 5 days enhances hESC cloning efficiency, suggesting that higher levels of OCT4A can support self-renewal. Overall, our results indicate that high levels of OCT4A increase hESC cloning efficiency and do not induce differentiation (whereas OCT4B expression cannot be induced in hESC), highlighting the importance of isoform-specific studies in a stable and inducible expression system for human OCT4. Additionally, we demonstrate the utility of an efficient method for conditional gene expression in hESC.

Optimizing retroviral gene expression for effective therapies

With their ability to integrate their genetic material into the target cell genome, retroviral vectors (RV) of both the gamma-retroviral (γ-RV) and lentiviral vector (LV) classes currently remain the most efficient and thus the system of choice for achieving transgene retention and therefore potentially long-term expression and therapeutic benefit. However, γ-RV and LV integration comes at a cost in that transcription units will be present within a native chromatin environment and thus be subject to epigenetic effects (DNA methylation, histone modifications) that can negatively impact on their function. Indeed, highly variable expression and silencing of γ-RV and LV transgenes especially resulting from promoter DNA methylation is well documented and was the cause of the failure of gene therapy in a clinical trial for X-linked chronic granulomatous disease. This review will critically explore the use of different classes of genetic control elements that can in principle reduce vector insertion site position effects and epigenetic-mediated silencing. These transcriptional regulatory elements broadly divide themselves into either those with a chromatin boundary or border function (scaffold/matrix attachment regions, insulators) or those with a dominant chromatin remodeling and transcriptional activating capability (locus control regions,, ubiquitous chromatin opening elements). All these types of elements have their strengths and weaknesses within the constraints of a γ-RV and LV backbone, showing varying degrees of efficacy in improving reproducibility and stability of transgene function. Combinations of boundary and chromatin remodeling; transcriptional activating elements, which do not impede vector production; transduction efficiency; and stability are most likely to meet the requirements within a gene therapy context especially when targeting a stem cell population.

Efficient lentiviral transduction and transgene expression in primary human B cells

Primary human B cells are an attractive target for gene-therapeutic applications, but have been found to be relatively resistant toward transduction with lentiviral vectors (LVVs), even though a number of different envelope pseudotypes were tested. Moreover, low transgene expression in primary human B cells has impeded the use of LVVs for this target cell. We investigated the transduction potential of gibbon-ape leukemia virus (GALV) Env-pseudotyped LVVs for primary human B cells. By establishing optimized transduction kinetics and multiplicities of infection, we were able to regularly obtain transduction efficiencies of more than 50% in CD40L-activated B cells. Noteworthy, with the use of GALV-pseudotyped LVVs we could achieve a more than 10-fold higher yield of transduced activated B cells in direct comparison with LVVs pseudotyped with measles virus glycoproteins. Phenotyping of transduced primary B cells revealed a majority of memory B cells, a long-lived phenotype, presumed to be well suited for enduring therapeutic interventions. Finally, by combining the enhancer (Eμ) and the matrix/scaffold-attachment regions (MARs) of the human immunoglobulin heavy chain with the promoter of spleen focus-forming virus (SFFV) we aimed at generating a novel LVV particularly suitable for B cell transgenesis. We show that the optimized vector facilitated significantly higher transgene expression in various B cell lines and, more importantly, primary human B cells (mean factor of three). In summary, we have established a novel protocol for the efficient lentiviral transduction of primary human B cells and have improved transgene expression in B cells by a specific vector modification.

Cloning and genomic nucleotide sequence of the matrix attachment region binding protein from the halotolerant alga Dunaliella salina

In our previous study, the sequence of a matrix attachment region binding protein (MBP) cDNA was cloned from the unicellular green alga Dunaliella salina. However, the nucleotide sequence of this gene has not been reported so far. In this paper, the nucleotide sequence of MBP was cloned and characterized, and its gene copy number was determined. The MBP nucleotide sequence is 5641 bp long, and interrupted by 12 introns ranging from 132 to 562 bp. All the introns in the D. salina MBP gene have orthodox splice sites, exhibiting GT at the 5' end and AG at the 3' end. Southern blot analysis showed that MBP only has one copy in the D. salina genome.

The GATA1-HS2 enhancer allows persistent and position-independent expression of a β-globin transgene

Gene therapy of genetic diseases requires persistent and position-independent expression of a therapeutic transgene. Transcriptional enhancers binding chromatin-remodeling and modifying complexes may play a role in shielding transgenes from repressive chromatin effects. We tested the activity of the HS2 enhancer of the GATA1 gene in protecting the expression of a β-globin minigene delivered by a lentiviral vector in hematopoietic stem/progenitor cells. Gene expression from proviruses carrying GATA1-HS2 in both LTRs was persistent and resistant to silencing at most integration sites in the in vivo progeny of human hematopoietic progenitors and murine long-term repopulating stem cells. The GATA1-HS2-modified vector allowed correction of murine β-thalassemia at low copy number without inducing clonal selection of erythroblastic progenitors. Chromatin immunoprecipitation studies showed that GATA1 and the CBP acetyltransferase bind to GATA1-HS2, significantly increasing CBP-specific histone acetylations at the LTRs and β-globin promoter. Recruitment of CBP by the LTRs thus establishes an open chromatin domain encompassing the entire provirus, and increases the therapeutic efficacy of β-globin gene transfer by reducing expression variegation and epigenetic silencing.

Development of B-lineage predominant lentiviral vectors for use in genetic therapies for B cell disorders

Sustained, targeted, high-level transgene expression in primary B lymphocytes may be useful for gene therapy in B cell disorders. We developed several candidate B-lineage predominant self-inactivating lentiviral vectors (LV) containing alternative enhancer/promoter elements including: the immunoglobulin β (Igβ) (B29) promoter combined with the immunoglobulin µ enhancer (EµB29); and the endogenous BTK promoter with or without Eµ (EµBtkp or Btkp). LV-driven enhanced green fluorescent protein (eGFP) reporter expression was evaluated in cell lines and primary cells derived from human or murine hematopoietic stem cells (HSC). In murine primary cells, EµB29 and EµBtkp LV-mediated high-level expression in immature and mature B cells compared with all other lineages. Expression increased with B cell maturation and was maintained in peripheral subsets. Expression in T and myeloid cells was much lower in percentage and intensity. Similarly, both EµB29 and EµBtkp LV exhibited high-level activity in human primary B cells. In contrast to EµB29, Btkp and EµBtkp LV also exhibited modest activity in myeloid cells, consistent with the expression profile of endogenous Bruton's tyrosine kinase (Btk). Notably, EµB29 and EµBtkp activity was superior in all expression models to an alternative, B-lineage targeted vector containing the EµS.CD19 enhancer/promoter. In summary, EµB29 and EµBtkp LV comprise efficient delivery platforms for gene expression in B-lineage cells.

Physiological and tissue-specific vectors for treatment of inherited diseases

After more than 1500 gene therapy clinical trials in the past two decades, the overall conclusion is that for gene therapy (GT) to be successful, the vector systems must still be improved in terms of delivery, expression and safety. The recent development of more efficient and stable vector systems has created great expectations for the future of GT. Impressive results were obtained in three primary immunodeficiencies and other inherited diseases such as congenital blindness, adrenoleukodystrophy or junctional epidermolysis bullosa. However, the development of leukemia in five children included in the GT clinical trials for X-linked severe combined immunodeficiency and the silencing of the therapeutic gene in the chronic granulomatous disease clearly showed the importance of improving safety and efficiency. In this review, we focus on the main strategies available to achieve physiological or tissue-specific expression of therapeutic transgenes and discuss the importance of controlling transgene expression to improve safety. We propose that tissue-specific and/or physiological viral vectors offer the best balance between efficiency and safety and will be the tools of choice for future clinical trials in GT of inherited diseases.

Was cDNA sequences modulate transgene expression of was promoter-driven lentiviral vectors

Abstract The development of vectors that express a therapeutic transgene efficiently and specifically in hematopoietic cells (HCs) is an important goal for gene therapy of hematological disorders. We have previously shown that a 500-bp fragment from the proximal Was gene promoter in a lentiviral vector (LV) was sufficient to achieve more than 100-fold higher levels of Wiskott-Aldrich syndrome protein in HCs than in nonhematopoietic cells (non-HCs). We show now that this differential was reduced up to 10 times when the enhanced green fluorescent protein gene (eGFP) was expressed instead of Was in the same LV backbone. Insertion of Was cDNA sequences downstream of eGFP in these LVs had a negative effect on transgene expression. This effect varied in different cell types but, overall, Was cDNA sequences increased the hematopoietic specificity of Was promoter-driven LV. We have characterized the minimal fragment required to increase hematopoietic specificity and have demonstrated that the mechanism involves Was promoter regulation and RNA processing. In addition, we have shown that Was cDNA sequences interfere with the enhancer activity of the woodchuck posttranscriptional regulatory element. These results represent the first data showing the role of Was intragenic sequences in gene regulation.

Lentiviral vectors for immune cells targeting

Lentiviral vectors (LVs) are efficient gene delivery vehicles suitable for delivering long-term transgene expression in various cell types. Engineering LVs to have the capacity to transduce specific cell types is of great interest to advance the translation of LVs toward the clinic. Here we provide an overview of innovative approaches to target LVs to cells of the immune system. In this overview we distinguish between two types of LV targeting strategies: (i) targeting of the vectors to specific cells by LV surface modifications, and (ii) targeting at the level of transgene transcription by insertion of tissue-specific promoters to drive transgene expression. It is clear that each strategy is of enormous value but ultimately combining these approaches may help reduce the effects of off-target expression and improve the efficiency and safety of LVs for gene therapy.

Targeted gene delivery to CD117-expressing cells in vivo with lentiviral vectors co-displaying stem cell factor and a fusogenic molecule

The development of a lentiviral system to deliver genes to specific cell types could improve the safety and the efficacy of gene delivery. Previously, we have developed an efficient method to target lentivectors to specific cells via an antibody-antigen interaction in vitro and in vivo. We report herein a targeted lentivector that harnesses the natural ligand-receptor recognition mechanism for targeted modification of c-KIT receptor-expressing cells. For targeting, we incorporate membrane-bound human stem cell factor (hSCF), and for fusion, a Sindbis virus-derived fusogenic molecule (FM) onto the lentiviral surface. These engineered vectors can recognize cells expressing surface CD117, resulting in efficient targeted transduction of cells in an SCF-receptor dependent manner in vitro, and in vivo in xenografted mouse models. This study expands the ability of targeting lentivectors beyond antibody targets to include cell-specific surface receptors. Development of a high titer lentivector to receptor-specific cells is an attractive approach to restrict gene expression and could potentially ensure therapeutic effects in the desired cells while limiting side effects caused by gene expression in non-target cells.

Targeting lentiviral vectors to antigen-specific immunoglobulins

Gene transfer into B cells by lentivectors can provide an alternative approach to managing B lymphocyte malignancies and autoreactive B cell-mediated autoimmune diseases. These pathogenic B cell populations can be distinguished by their surface expression of monospecific immunoglobulin. Development of a novel vector system to deliver genes to these specific B cells could improve the safety and efficacy of gene therapy. We have developed an efficient method to target lentivectors to monospecific immunoglobulin-expressing cells in vitro and in vivo. We were able to incorporate a model antigen CD20 and a fusogenic protein derived from the Sindbis virus as two distinct molecules into the lentiviral surface. This engineered vector could specifically bind to cells expressing surface immunoglobulin recognizing CD20 (alphaCD20), resulting in efficient transduction of target cells in a cognate antigen-dependent manner in vitro, and in vivo in a xenografted tumor model. Tumor suppression was observed in vivo, using the engineered lentivector to deliver a suicide gene to a xenografted tumor expressing alphaCD20. These results show the feasibility of engineering lentivectors to target immunoglobulin- specific cells to deliver a therapeutic effect. Such targeting lentivectors also could potentially be used to genetically mark antigen-specific B cells in vivo to study their B cell biology.

Chromatin, gene silencing and HIV latency

Cellular defence mechanisms against HIV contribute to its persistence.

One of the cellular defenses against virus infection is the silencing of viral gene expression. There is evidence that at least two gene-silencing mechanisms are used against the human immuno-deficiency virus (HIV). Paradoxically, this cellular defense mechanism contributes to viral latency and persistence, and we review here the relationship of viral latency to gene-silencing mechanisms.

Beta-globin LCR and intron elements cooperate and direct spatial reorganization for gene therapy

The Locus Control Region (LCR) requires intronic elements within β-globin transgenes to direct high level expression at all ectopic integration sites. However, these essential intronic elements cannot be transmitted through retrovirus vectors and their deletion may compromise the therapeutic potential for gene therapy. Here, we systematically regenerate functional β-globin intron 2 elements that rescue LCR activity directed by 5′HS3. Evaluation in transgenic mice demonstrates that an Oct-1 binding site and an enhancer in the intron cooperate to increase expression levels from LCR globin transgenes. Replacement of the intronic AT-rich region with the Igμ 3′MAR rescues LCR activity in single copy transgenic mice. Importantly, a combination of the Oct-1 site, Igμ 3′MAR and intronic enhancer in the BGT158 cassette directs more consistent levels of expression in transgenic mice. By introducing intron-modified transgenes into the same genomic integration site in erythroid cells, we show that BGT158 has the greatest transcriptional induction. 3D DNA FISH establishes that induction stimulates this small 5′HS3 containing transgene and the endogenous locus to spatially reorganize towards more central locations in erythroid nuclei. Electron Spectroscopic Imaging (ESI) of chromatin fibers demonstrates that ultrastructural heterochromatin is primarily perinuclear and does not reorganize. Finally, we transmit intron-modified globin transgenes through insulated self-inactivating (SIN) lentivirus vectors into erythroid cells. We show efficient transfer and robust mRNA and protein expression by the BGT158 vector, and virus titer improvements mediated by the modified intron 2 in the presence of an LCR cassette composed of 5′HS2-4. Our results have important implications for the mechanism of LCR activity at ectopic integration sites. The modified transgenes are the first to transfer intronic elements that potentiate LCR activity and are designed to facilitate correction of hemoglobinopathies using single copy vectors.

Expression of the β-globin gene is regulated by interactions between a distant Locus Control Region (LCR) and regulatory elements in or near the gene. We previously showed that LCR activity requires specific β-globin intron elements to consistently activate transgene expression in mice. These important intronic elements fail to transmit through lentivirus vectors designed for gene therapy of Sickle Cell Anemia. In this study, we identify intron modifications that reveal functional cooperation between the β-globin intronic enhancer and an intronic Oct-1 site. LCR activity in transgenic mice is also potentiated by an intronically located Igμ 3′MAR element. During induction of erythroid gene expression, the modified intron directs relocalization of the transgene away from the nuclear periphery towards more central neighbourhoods, and this movement mimics relocalization by the endogenous β-globin locus. Lentivirus vectors with the modified intron produce high titer virus stocks that express the transgene to therapeutic levels in erythroid cells. These findings have implications for understanding the mechanism of LCR activity, and for designing safe and effective lentivirus vectors for gene therapy.

Repopulation of B-lymphocytes with restricted gene expression using haematopoietic stem cells engineered with lentiviral vectors

B-lymphocytes play a key role in the pathogenesis of many immune-mediated diseases, such as autoimmune and atopic diseases. Therefore, targeting B-lymphocytes provides a rationale for refining strategies to treat such diseases for long-term clinical benefits and minimal side effects. In this study we describe a protocol for repopulating irradiated mice with B-lymphocytes engineered for restricted expression of transgenes using haematopoietic stem cells. A self-inactivating lentiviral vector, which encodes enhanced green fluorescence protein (EGFP) from the spleen focus-forming virus (SFFV) promoter, was used to generate new vectors that permit restricted EGFP expression in B-lymphocytes. To achieve this, the SFFV promoter was replaced with the B-lymphocyte-restricted CD19 promoter. Further, an immunoglobulin heavy chain enhancer (Emu) flanked by the associated matrix attachment regions (MARs) was inserted upstream of the CD19 promoter. Incorporation of the Emu-MAR elements upstream of the CD19 promoter resulted in enhanced, stable and selective transgene expression in human and murine B-cell lines. In addition, this modification permitted enhanced selective EGFP expression in B-lymphocytes in vivo in irradiated mice repopulated with transduced bone marrow haematopoietic stem cells (BMHSCs). The study provides evidence for the feasibility of targeting B-lymphocytes for therapeutic restoration of normal B-lymphocyte functions in patients with B-cell-related diseases.

Development of an enhanced B-specific lentiviral vector expressing BTK: a tool for gene therapy of XLA

Further development of haematopoietic stem cell (HSC) gene therapy will depend on enhancement of gene transfer safety: ad hoc improvement of vector design relating to each particular disease is thus a crucial issue for HSC gene therapy. We modified a previously described lentiviral vector by adding the Emumar B-specific enhancer to a human CD19 promoter-derived sequence (Mol Ther 2004;10:45-56). We thus significantly improved the level of expression of the green fluorescent protein (GFP) reporter gene while retaining the specificity of expression in B-cell progeny of transduced human CD34+ progenitor cells obtained from cord blood or adult bone marrow. Indeed, GFP was strongly expressed from early medullary pro-B cells to splenic mature B cells whereas transgene expression remained low in transduced immature progenitors as in myeloid and T-lymphoid progeny retrieved from xenografted NOD/SCID/gammac(null) mice. Using this lentiviral vector, we further demonstrated the possibility to express a functional human BTK protein in long-term human CD34+ cell B-lymphoid progeny. This newly designed lentiviral vector fulfils one of the pre-requisites for the development of efficient and safe gene therapy for X-linked agammaglobulinaemia, the most common primary humoral immunodeficiency disorder.

Cell-specific and efficient expression in mouse and human B cells by a novel hybrid immunoglobulin promoter in a lentiviral vector

The expression of genes specifically in B cells is of great interest in both experimental immunology as well as in future clinical gene therapy. We have constructed a novel enhanced B cell-specific promoter (Igk-E) consisting of an immunoglobulin kappa (Igk) minimal promoter combined with an intronic enhancer sequence and a 3' enhancer sequence from Ig genes. The Igk-E promoter was cloned into a lentiviral vector and used to control expression of enhanced green fluorescent protein (eGFP). Transduction of murine B-cell lymphoma cell lines and activated primary splenic B cells, with IgK-E-eGFP lentivirus, resulted in expression of eGFP, as analysed by flow cytometry, whereas expression in non-B cells was absent. The specificity of the promoter was further examined by transducing Lin(-) bone marrow with Igk-E-eGFP lentivirus and reconstituting lethally irradiated mice. After 16 weeks flow cytometry of lymphoid tissues revealed eGFP expression by CD19+ cells, but not by CD3+, CD11b+, CD11c+ or Gr-1+ cells. CD19+ cells were comprised of both marginal zone B cells and recirculating follicular B cells. Activated human peripheral mononuclear cells were also transduced with Igk-E-eGFP lentivirus under conditions of selective B-cell activation. The Igk-E promoter was able to drive expression of eGFP only in CD19+ cells, while eGFP was expressed by both spleen focus-forming virus and cytomegalovirus constitutive promoters in CD19+ and CD3+ lymphocytes. These data demonstrate that in these conditions the Igk-E promoter is cell specific and controls efficient expression of a reporter protein in mouse and human B cells in the context of a lentiviral vector.

Development of lentiviral vectors with regulated respiratory epithelial expression in vivo

Development of gene transfer vectors with regulated, lung-specific expression will be a useful tool for studying lung biology and developing gene therapies. In this study we constructed a series of lentiviral vectors with regulatory elements predicted to produce lung-specific transgene expression: the surfactant protein C promoter (SPC) for alveolar epithelial type II cell (AECII) expression, the Clara cell 10-kD protein (CC10) for Clara cell expression in the airway, and the Jaagskiete sheep retrovirus (JSRV) promoter for expression in both cell types. Transgene expression from the SPC and CC10 vectors was restricted to AECII and Clara cell lines, respectively, while expression from the JSRV vector was observed in multiple respiratory and nonrespiratory cell types. After intratracheal delivery of lentivector supernatant to mice, transgene expression was observed in AECII from the SPC lentivector, and in Clara cells from the CC10-promoted lentivector. Transgene expression was not detected in nonrespiratory tissues after intravenous delivery of CC10 and SPC lentiviral vectors to murine recipients. In summary, incorporation of genomic regulatory elements from the SPC and CC10 genes resulted in respiratory specific transgene expression in vitro and in vivo. These vectors will provide a useful tool for the study of lung biology and the development of gene therapies for lung disorders.

Targeting lentiviral vectors to specific cell types in vivo

We have developed an efficient method to target lentivirus-mediated gene transduction to a desired cell type. It involves incorporation of antibody and fusogenic protein as two distinct molecules into the lentiviral surface. The fusogen is constructed by modifying viral envelope proteins, so that they lack the ability to bind to their cognate receptor but still retain the ability to trigger pH-dependent membrane fusion. Thus, the specificity of such a lentiviral vector is solely determined by the antibody, which is chosen to recognize a specific surface antigen of the desired cell type. This specific binding then induces endocytosis of the surface antigen, bringing the lentivirus into an endosome. There, the fusogen responds to the low pH environment and mediates membrane fusion, allowing the virus core to enter the cytosol. Using CD20 as a target antigen for human B cells, we have demonstrated that this targeting strategy is effective both in vitro and in intact animals. This methodology is flexible and can be extended to other forms of cell type-specific recognition to mediate targeting. The only requirement is that the antibody (or other binding protein) must be endocytosed after interaction with its cell surface-binding determinant.

Retrovirus Vectors: Toward the Plentivirus?

Recombinant retroviral vectors based upon simple gammaretroviruses, complex lentiviruses, or potentially nonpathogenic spumaviruses represent relatively well characterized tools that are widely used for stable gene transfer. Different members of the Retroviridae family have developed distinct and potentially useful features related to their life cycle. These natural differences can be exploited for specialized applications in gene therapy and could conceivably be combined to create future retroviral hybrid vectors, ideally incorporating the following features: an efficient, noncytopathic packaging system with low likelihood of recombination; serum resistance; an ability to pseudotype with cell-specific envelopes; high-fidelity reverse transcription before cell entry; unrestricted cytoplasmic transport and nuclear import; an insulated expression cassette; specific chromosomal targeting; and physiologic or regulated levels of transgene expression. We envisage that, compared to contemporary vectors, a hybrid vector combining these properties would have increased therapeutic efficacy and an enhanced biosafety profile. Many of the above goals will require the inclusion of nonretroviral components into vector particles or transgenes.

Use of bone marrow-derived macrophages to model murine innate immune responses

The innate immune system is composed of neutrophils and monocyte/macrophages. As a cell type, bone marrow-derived macrophage (BMM) are easier to study than neutrophils since they are still capable of cell division and have a longer life span. However, in comparison with neutrophils, few methodological studies on the production of reactive oxygen species (ROS) by such macrophages have been reported. Here we present studies on ROS production of this cell type under various conditions including the use of different priming and stimulating agents. In addition, we report that the de novo adhesion of BMM to tissue culture plates induces superoxide anion production and this can be further enhanced by stimulation with PMA. BMM are able to adhere to endothelial cells that have been activated by TNF-alpha exposure, and under these circumstances also generate ROS. We explored different methods to introduce gene products into BMM without activating them to avoid complicating subsequent studies of ROS production. Infection with lentiviral vectors was very efficient, allowed long-term expression and did not activate the BMM. We conclude that BMM are very suitable for the biochemical study of the oxidative burst.

Mutagenesis and oncogenesis by chromosomal insertion of gene transfer vectors

Increasing evidence reveals that random insertion of gene transfer vectors into the genome of repopulating hematopoietic cells may alter their fate in vivo. Although most insertional mutations are expected to have few if any consequences for cellular survival, clonal dominance caused by retroviral vector insertions in (or in the vicinity of) proto-oncogenes or other signaling genes has been described for both normal and malignant hematopoiesis. Important insights into these side effects were initially obtained in murine models. Results from ongoing clinical studies have revealed that similar adverse events may also occur in human gene therapy. However, it remains unknown to what extent the outcome of insertional mutagenesis induced by gene vectors is related to (1) the architecture and type of vector used, (2) intrinsic properties of the target cell, and (3) extrinsic and potentially disease-specific factors influencing clonal competition in vivo. This review discusses reports addressing these questions, underlining the need for models that demonstrate and quantify the functional consequences of insertional mutagenesis. Improving vector design appears to be the most straightforward approach to increase safety, provided all relevant cofactors are considered.

Sea urchin arylsulfatase insulator exerts its anti-silencing effect without interacting with the nuclear matrix

Chromatin insulators have been shown to stabilize transgene expression. Although insulators have been suggested to regulate the subcellular localization of chromosomes, it is still unclear whether this property is important for their anti-silencing activity. To investigate the underlying mechanisms governing the anti-silencing function of insulators, we studied the association of sea urchin arylsulfatase insulator (ArsI) with the nuclear matrix, which is a key component of the subnuclear localization of the genome. ArsI did not potentiate the nuclear matrix association with the transgene, even though it showed strong anti-silencing activity. This observation was in clear contrast to the results of the experiment using a human interferon-beta scaffold attachment region, in which the anti-silencing effect coincided with the enhanced matrix association. Chromatin immunoprecipitation analyses suggested that the absence of the matrix binding by ArsI was due to a lack of its binding to CCCTC-binding factor (CTCF), a protein known to be associated with matrix binding by chicken beta-globin insulator. Furthermore, ArsI maintained the nucleosome occupancy within the transgene at a constant level during long-term culture, although ArsI itself was not a nucleosome-excluding sequence. Taken together, these results suggest that this insulator exerts its anti-silencing activity by counteracting silencing-associated factors to maintain local chromatin environment, rather than by remodeling the subnuclear localization of the transgene locus.

Matrix attachment regions as targets for retroviral integration

BACKGROUND

The randomness of retroviral integration has been debated for many years. Recent evidence indicates that integration site selection is not random, and that it is influenced by both viral and cellular factors. To study the role of DNA structure in site selection, retroviral integration near matrix attachment regions (MARs) was analyzed for three different groups of retroviruses. The objective was to assess whether integration near MARs may be a factor for integration site selection.

RESULTS

Results indicated that MLV, SL3-3 MuLV, HIV-1 and HTLV-1 integrate preferentially near MARs, specifically within 2-kilobases (kb). In addition, a preferential position and orientation relative to the adjacent MAR was observed for each virus. Further analysis of SL3-3 MuLV insertions in common integration sites (CISs) demonstrated a higher frequency of integration near MARs and an orientation preference that was not observed for integrations outside CISs.

CONCLUSION

These findings contribute to a growing body of evidence indicating that retroviral integration is not random, that MARs influence integration site selection for some retroviruses, and that integration near MARs may have a role in the insertional activation of oncogenes by gammaretroviruses.

Restriction of transgene expression to the B-lymphoid progeny of human lentivirally transduced CD34+ cells

Development of gene transfer strategies will necessitate improved efficiency and control of transduction and transgene expression. We here provide evidence that targeting expression of the GFP reporter gene to the B-lymphoid progeny of genetically modified human hematopoietic progenitor cells can be achieved through the insertion of regulatory sequences from the human CD19 gene promoter into a lentiviral vector. Based on a bioinformatics approach, three human CD19-derived sequences were designed and inserted into a self-inactivated lentiviral vector backbone upstream of the GFP gene: S.CD19 (230 bp), M.CD19 (464 bp), and L.CD19 (1274 bp). These new lentiviral vectors efficiently transduced cord blood CD34(+) cells. The M.CD19 and especially L.CD19 sequences preferentially targeted GFP expression to in vitro and in vivo differentiated CD19(+) progeny; moreover, transgene expression was detected from the CD34(+) pro/pre-B cell to the mature peripheral IgM(+) B cell stage. In contrast, GFP expression was weak or absent in primary T-lymphoid and uncommitted progenitor cells or in erythroid, natural killer, or myeloid differentiated cells. Such B-lineage-specific lentiviral vectors may be useful for correcting inherited disorders that affect B-lymphoid cells or for deciphering the transcriptional program that controls B cell commitment and differentiation.

B-cell-specific transgene expression using a self-inactivating retroviral vector with human CD19 promoter and viral post-transcriptional regulatory element

Retroviral gene transfer resulting in transgene expression selectively restricted to specific cell lineages would be desirable for many gene therapeutic applications. Such transcriptional targeting of retroviruses can be accomplished by employing eukaryotic control elements in self-inactivating (SIN) retroviral vectors, but use of these vectors is complicated by an accompanying reduction in viral titers. To overcome this restriction and address the influence of the post-transcriptional regulatory element of the Woodchuck hepatitis virus (WPRE) on viral titers and transgene expression, we developed SIN-vectors with and without WPRE. Using the enhancer-promoter of the Spleen Focus Forming virus (SFFV) to direct eGFP expression to multiple hematopoietic lineages, we show that WPRE significantly (>10 x) increased viral titers (>10(6) per ml of unconcentrated supernatant) and transgene expression in NIH3T3 cells in vitro. Gene expression in vivo was significantly lowered in lymphoid cells, but not in myeloid cells when WPRE was present. Furthermore, the use of WPRE in combination with the B-cell lineage-specific CD19 promoter significantly increased viral titers and allowed targeting of transgene expression by SIN-vectors specifically to B cells throughout their development in primary and secondary lymphoid organs.

Efficient Marking of Murine Long-Term Repopulating Stem Cells Targeting Unseparated Marrow Cells at Low Lentiviral Vector Particle Concentration

HIV-1-derived lentivirus vectors offer unique biological properties for gene delivery to hematopoietic stem cells and, when used at high multiplicities of infection (m.o.i.), permit efficient gene transfer after minimal target cell stimulation. However, such a strategy has been shown to promote multicopy proviral integration, potentially increasing the risk of insertional mutagenesis. To minimize cell manipulation, we targeted unseparated marrow and demonstrated that transduction at an m.o.i. of 1 resulted in up to 12% vector-modified peripheral blood leukocytes and successful repopulation of secondary recipients with vector-marked cells. Real-time PCR showed on average 1.8 proviral integrants per GFP-marked cell. By comparison, a cohort of animals transplanted with cells transduced at m.o.i. of 10 under otherwise unchanged conditions showed up to 45% marking with an average of 7 copies per GFP-expressing cell. Both m.o.i. groups demonstrated sustained proviral expression with stable GFP fluorescence intensity. In summary, we have identified conditions for lentiviral gene transfer involving minimal ex vivo target cell manipulation and have shown that the m.o.i. is a critical determinant of proviral copy number in lentivirus-transduced murine long-term repopulating cells. Thus, gene transfer efficiencies may be limited when single-copy integration is desired and additional strategies such as in vivo selection may be required to improve the frequency of gene-modified cells.

Prospects and implications of using chromatin insulators in gene therapy and transgenesis

Gene therapy has emerged from the idea of inserting a wild-type copy of a gene in order to restore the proper expression and function of a damaged gene. Initial efforts have focused on finding the proper vector and delivery method to introduce a corrected gene to the affected tissue or cell type. Even though these first attempts are clearly promising, several problems remain unsolved. A major problem is the influence of chromatin structure on transgene expression. To overcome chromatin-dependent repressive transgenic states, researchers have begun to use chromatin regulatory elements to drive transgene expression. Insulators or chromatin boundaries are able to protect a transgene against chromatin position effects at their genomic integration sites, and they are able to maintain transgene expression for long periods of time. Therefore, these elements may be very useful tools in gene therapy applications for ensuring high-level and stable expression of transgenes.