Impact of Promoter-Independent CpG-Rich A2UCOE Subregions on Transgene Expression

Modified Lentiviral LTRs Allow Flp Recombinase–mediated Cassette Exchange and In Vivo Tracing of “Factor-free” Induced Pluripotent Stem Cells

Desmin-regulated Lentiviral Vectors for Skeletal Muscle Gene Transfer

Lentiviral Vector Design and Imaging Approaches to Visualize the Early Stages of Cellular Reprogramming

Extensive Methylation of Promoter Sequences Silences Lentiviral Transgene Expression During Stem Cell Differentiation In Vivo

Lentiviral vectors (LVs) are considered one of the most promising vehicles to efficiently deliver genetic information for basic research and gene therapy approaches. Combining LVs with drug-inducible expression systems should allow tight control of transgene expression with minimal side effect on relevant target cells. A new doxycycline-regulated system based on the original TetR repressor was developed in 1998 as an alternative to the TetR-VP16 chimeras (tTA and rtTA) to avoid secondary effects due to the expression of transactivator domains. However, previously described TetR-based systems required cell cloning and/or antibiotic selection of tetracycline-responsive cells in order to achieve good regulation. In the present manuscript we have constructed a dual Tet-ON system based on two lentiviral vectors, one expressing the TetR through the spleen focus forming virus (SFFV) promoter (STetR) and a second expressing eGFP through the regulatable CMV-TetO promoter (CTetOE). Using these vectors we have demonstrated that the TetR repressor, contrary to the reverse transactivator (rtTA), can be expressed in excess to bind and modulate a high number of TetO operons. We have also showed that this dual vector system can generate regulatable bulk cell lines (expressing high levels of TetR) that are able to modulate transgene expression either by varying doxycycline concentration and/or by varying the amount of CTetOE vector genomes per cell. Based on these results we have developed a new all-in-one lentiviral vector (CEST) driving the expression of TetR through the SFFV promoter and the expression of eGFP through the doxycycline-responsive CMV-TetO operon. This vector efficiently produced Tet-ON regulatable immortalized (293T) and primary (human mesenchymal stem cells and human primary fibroblasts) cells. Bulk doxycycline-responsive cell lines express high levels of the transgene with low amount of doxycycline and are phenotypically indistinct from its parental cells.

Efficient Reprogramming of Human Cord Blood CD34+ Cells Into Induced Pluripotent Stem Cells With OCT4 and SOX2 Alone

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.

Immune tolerance to self-antigens is a complex process that utilizes multiple mechanisms working in concert to maintain homeostasis and prevent autoimmunity. Considerable progress in deciphering the mechanisms controlling the activation or deletion of T cells has been made by using T cell receptor (TCR) transgenic mice. One such model is the F5 model in which CD8 T cells express a TCR specific for an epitope derived from the influenza NP68 protein. Our aim was to create transgenic mouse models expressing constitutively the NP68 epitope fused to enhanced green fluorescent protein (EGFP) in order to assess unambiguously the relative levels of NP68 epitope expressed by single cells. We used a lentiviral-based approach to generate two independent transgenic mouse strains expressing the fusion protein EGFP-NP68 under the control of CAG (CMV immediate early enhancer and the chicken β-actin promoter) or spleen focus-forming virus (SFFV) promoters. Analysis of the pattern of EGFP expression in the hematopoietic compartment showed that CAG and SFFV promoters are differentially regulated during T cell development. However, both promoters drove high EGFP-NP68 expression in dendritic cells (pDCs, CD8α(+) cDCs, and CD8α(-) cDCs) from spleen or generated in vitro following differentiation from bone-marrow progenitors. NP68 epitope was properly processed and successfully presented by dendritic cells (DCs) by direct presentation and cross-presentation to F5 CD8 T cells. The models presented here are valuable tools to investigate the priming of F5 CD8 T cells by different subsets of DCs.

Sexually Dimorphic Patterns of Episomal rAAV Genome Persistence in the Adult Mouse Liver and Correlation With Hepatocellular Proliferation

A recent gamma-retroviral clinical Chronic Granulomatous Disease (CGD) gene therapy (GT) trial achieved proof-of-concept but was accompanied by activation of oncogenes and transgene silencing. The ubiquitous chromatin opening element (UCOE) comprises the sequences of two divergently oriented house-keeping gene promoters and is known to have anti-silencing properties. In a screen we identified two novel UCOE constructs that prevent adjacent promoter methylation in P19 cells. Experiments were continued with the shorter UCOE constructs in induced pluripotent stem cells (iPSC) derived from a p47phox-deficient CGD patient. The iPSC line was transduced with the lentiviral GT vectors expressing P47 under the constitutively active SFFV promoter with UCOE element (UCOE_SF) and without UCOE element (SF) adjacent to the SFFV promoter. The iPSC were expanded before propagation towards neutrophils. 20 days after transduction the UCOE_SF vector was protected from methylation in iPSC as previously shown in P19 cells, whereas the SF vector was heavily methylated in iPSC. The UCOE_SF vector maintained stable transgene expression in iPSC, macrophages and neutrophils, whereas the SF vector was strongly silenced. The UCOE_SF vector stably restored ROS production in neutrophils, whereas for the SF vector the count of ROS producing cells was marginal. To conclude, we have shown that the prevention of transgene silencing by UCOE is functionally and mechanistically preserved upon terminal neutrophil differentiation.

To date, the production of antibodies (mAbs) usually faces the risks of transgene expression reduction and instability, especially after long-time culture. The inclusion of ubiquitous chromatin opening element (UCOE) into expression vectors was reported to enhance protein production and maintain transgene expression stability in CHO cell lines. Thus, we investigate the effects of UCOE on recombinant monoclonal anti-TNFα antibody (mAbTNFα) production and expression stability in CHO-DG44 cells. In our study, non-UCOE and UCOE-based vectors encoding mAbTNFα were constructed and introduced into the CHO-DG44 cells. Cell pools and single-cell clones were obtained by selecting transfected cells with G418, amplifying them by treatment with methotrexate (MTX), and isolating them by limiting dilution. The effects of UCOE on mAb production and stable transgene expression in transfected cells were analyzed via the correlation between mAb yields and mRNA expression level variations, and gene copy number changes. The UCOE pool exhibited higher mAb yield compared to non-UCOE pool. The UCOE was associated with higher transgene transcriptional activity, leading to improvement of mAb production after MTX-mediated gene amplification. The incorporation of UCOE generated cells allowed isolation of greater numbers of positive clones with higher expression. Despite the slightly decreased mAb yield, UCOE clones still retain stable long-term expression in the absence of selective pressure, which was explained by the loss of transgene copies rather than due to the decline of transcriptional activity. In addition, the purified mAb had primary chemical and biological characteristics similar to those of adalimumab. The results showed that the incorporation of UCOE within vectors provides significant advantages in the generation of high-producing clones, enhancement of mAb production, and improvement of gene expression stability.

Objectives:Lentiviral vectors have been used successfully to rapidly produce decigram quantities of active recombinant proteins in mammalian cell lines. To optimize the protein production platform, the roles of Ubiquitous Chromatin Opening Element (UCOE), an insulator, and selected promoters were evaluated based on efficiency and stability of foreign gene expression mediated by lentiviral vectors.Methods: Five lentiviral vectors, pFIN-EF1α-GFP-2A-mCherH-WPRE containing EF1α promoter and HS4 insulator, p'HR.cppt.3'1.2kb-UCOE-SFFV-eGFP containing SFFV promoter and UCOE, pTYF-CMV(β-globin intron)-eGFP containing CMV promoter and β-globin intron, pTYF-CMV-eGFP containing CMV promoter, and pTYF-EF1α-eGFP with EF1α promoter were packaged, titered, and then transduced into 293T cells (1000 viral genomes per cell). The transduced cells were passaged once every three days at a ratio of 1:10. Expression level and stability of the foreign gene, green fluorescence protein (GFP), was evaluated using fluorescent microscopy and flow cytometry. Furthermore, we constructed a hepatitis C virus (HCV) E1 recombinant lentiviral vector, pLV-CMV-E1, driven by the CMV promoter. This vector was packaged and transduced into 293T cells, and the recombinant cell lines with stable expression of E1 protein were established by limiting dilution.Results:GFP expression in 293T cells transduced with the five lentiviral vectors peaked between passages 3 and 5 and persisted for more than 5 weeks. The expression was prolonged in the cells transduced with TYF-CMV (β-globin intron)-eGFP or TYF-CMV-eGFP, demonstrating less than a 50% decrease even at 9 weeks post transduction (p>0.05). The TYF-CMV-eGFP-transduced cells began with a higher level of GFP expression than other vectors did. The percentage of GFP positive cells for any of the five lentiviral vectors sustained over time. Moreover, the survival rates of all transfected cells exceeded 80% at both 5 and 9 weeks post transduction. Surprisingly, neither the HS4 insulator nor the UCOE sequence improved the GFP expression level or stability. Clonal cell lines with HCV E1 gene were generated from LV-CMV-E1 vector-infected 293T cells. A representative recombinant cell line maintained stable E1expression for at least 9 weeks without significant difference in morphology compared with untreated 293T cells.Conclusion: The results suggest that all five vectors can stably transduce 293T cells, producing long term transgene expression with different efficiencies. However, neither the insulator nor the UCOE improved the GFP expression. The vectors containing the promoter CMV or CMV (β-globin intron) generated the highest gene expressions, manifesting as more favorable candidates for recombinant protein production in HEK293T cells.

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.

Aim: The A2UCOE, a well-characterized chromatin-modifying element originating from a constitutively expressed human gene locus, promotes consistent and durable gene activity, even when foreign DNA sequences are inserted into densely packed heterochromatin regions. The aim of this study is to examine the Daedalus fragment in A2UCOE to identify key sub-regions responsible for its prominent chromatin opening activity. This would enable the discovery of a minimal yet fully functional element, allowing for more efficient utilization of vector capacity to accommodate therapeutic transgenes when incorporated into lentiviral vectors (LVs). Method: To assess the chromatin-opening activity of the Daedalus sub-region within the A2UCOE, lentiviral vectors carrying eGFP reporter constructs were generated and transduced into murine embryonal carcinoma cell lines (P19 and F9). Transgene expression stability was assessed across both pluripotent cells and those differentiated with retinoic acid. HEK293T cells were used for lentiviral packaging. Plasmid propagation was performed in E. coli DH5α, and standard molecular cloning techniques were applied. Flow cytometry was used to measure eGFP expression levels, and significance was assessed via Student’s t-test (p < 0.05). Results: Flow cytometry and RT-qPCR analyses revealed that the positive control vector (1.5A2UCOE-SEW) maintained stable eGFP expression in both differentiated states of P19 and F9 cells, whereas the UCOE vectors named Daedalus-F and Daedalus-R were unable to prevent transgene silencing. In undifferentiated cultures, eGFP expression from these vectors decreased by 40–50% within two weeks, with a similar decline observed in differentiated cells. The average vector copy numbers remained stable, indicating transcriptional silencing rather than vector loss. Conclusion: The Daedalus sub-region of A2UCOE alone could not prevent transgene silencing in pluripotent or differentiated cells, indicating additional A2UCOE elements are needed for stable long-term expression.

Hematopoietic Stem Cell (HSC) targeted gene transfer is an attractive treatment option for a number of hematopoietic disorders caused by single gene defects. However, extensive methylation of promoter sequences results in silencing of therapeutic gene expression. The choice of an appropriate promoter is therefore crucial for reproducible, stable and long-term transgene expression in clinical gene therapy. Recent studies suggest efficient and stable expression of transgenes from the ubiquitous chromatin opening element (UCOE) derived from the human HNRPA2B1-CBX3 locus can be achieved in murine HSC. Here, we compared the use of HNRPA2B1-CBX3 UCOE (A2UCOE)-mediated transgene regulation to two other frequently used promoters namely EF1α and PGK in human fetal liver-derived HSC (hflHSC). Efficient transduction of hflHSC with a lentiviral vector containing an HNRPA2B1-CBX3 UCOE-eGFP (A2UCOE-eGFP) cassette was achieved at higher levels than that obtained with umbilical cord blood derived HSC (3.1x; p<0.001). While hflHSC were readily transduced with all three test vectors (A2UCOE-eGFP, PGK-eGFP and EF1α-eGFP), only the A2-UCOE construct demonstrated sustained transgene expression in vitro over 24 days (p<0.001). In contrast, within 10 days in culture a rapid decline in transgene expression in both PGK-eGFP and EF1α-eGFP transduced hflHSC was seen. Subsequently, injection of transduced cells into immunodeficient mice (NOD/SCID/Il2rg -/-) demonstrated sustained eGFP expression for the A2UCOE-eGFP group up to 10 months post transplantation whereas PGK-eGFP and EF1α-eGFP transduced hflHSC showed a 5.1 and 22.2 fold reduction respectively over the same time period. We conclude that the A2UCOE allows a more efficient and stable expression in hflHSC to be achieved than either the PGK or EF1α promoters and at lower vector copy number per cell.