The cHS4 Chromatin Insulator Reduces the Rate of Retroviral Vector-Mediated Gene Dysregulation Associated with Aberrant Vector Transcription.

Integrating gammaretroviral vectors can dysregulate the expression of cellular genes through a variety of mechanisms, leading to genotoxicity and malignant transformation. Although most attention has focused on the activation of cellular genes by vector enhancers, aberrant fusion transcripts involving cellular gene sequences and vector promoters, vector splice elements, and vector transcription termination sequences have also been mechanistically associated with dysregulated expression of cellular genes. Chromatin insulators have emerged as an effective tool for reducing the frequency of vector-mediated genotoxicity and malignant transformation and have been shown to block the activation of cellular genes by vector enhancers. We report here evidence that flanking a gammaretroviral reporter vector with the cHS4 chromatin insulator also reduces the frequency of vector-mediated cellular gene dysregulation associated with aberrant vector transcripts, including vector transcription run-through and aberrant splicing. We demonstrate that the cHS4 element does not function to terminate transcription directly, implicating other mechanisms for this activity.

A hyperactive Mpl-based cell growth switch drives macrophage-associated erythropoiesis through an erythroid-megakaryocytic precursor.

Several approaches for controlling hematopoietic stem and progenitor cell expansion, lineage commitment, and maturation have been investigated for improving clinical interventions. We report here that amino acid substitutions in a thrombopoietin receptor (Mpl)--containing cell growth switch (CGS) extending receptor stability improve the expansion capacity of human cord blood CD34(+) cells in the absence of exogenous cytokines. Activation of this CGS with a chemical inducer of dimerization (CID) expands total cells 99-fold, erythrocytes 70-fold, megakaryocytes 0.5-fold, and CD34(+) stem/progenitor cells 4.4-fold by 21 days of culture. Analysis of cells in these expanded populations identified a CID-dependent bipotent erythrocyte-megakaryocyte precursor (PEM) population, and a CID-independent macrophage population. The CD235a(+)/CD41a(+) PEM population constitutes up to 13% of the expansion cultures, can differentiate into erythrocytes or megakaryocytes, exhibits very little expansion capacity, and exists at very low levels in unexpanded cord blood. The CD206(+) macrophage population constitutes up to 15% of the expansion cultures, exhibits high-expansion capacity, and is physically associated with differentiating erythroblasts. Taken together, these studies describe a fundamental enhancement of the CGS expansion platform, identify a novel precursor population in the erythroid/megakaryocytic differentiation pathway of humans, and implicate an erythropoietin-independent, macrophage-associated pathway supporting terminal erythropoiesis in this expansion system.

Long-term regulation of genetically modified primary hematopoietic cells in dogs.

We report long-term results from a large animal model of in vivo selection. Nine years ago, we transplanted two dogs (E900 and E958) with autologous marrow CD34(+) cells that had been transduced with a gammaretrovirus vector encoding a conditionally activatable derivative of the thrombopoietin receptor. Receptor activation through administration of a chemical inducer of dimerization (CID) (AP20187 or AP1903) confers a growth advantage. We previously reported responses to two 30-day intravenous (i.v.) courses of AP20187 administered within the first 8 months post-transplantation. We now report responses to 5-day subcutaneous (s.c.) courses of AP20187 or AP1903 at months 14, 90, and 93 (E900), or month 18 (E958), after transplantation. Long-term monitoring showed no rise in transduced cells in the absence of drug. Retroviral insertion site analysis showed that 4 of 6 (E958) and 5 of 12 (E900) transduced hematopoietic cell clones persisted lifelong. Both dogs were euthanized for reasons unrelated to the gene therapy treatment at 8 years 11 months (E958) and 11 years 1 month (E900) of age. Three clones from E900 remained detectable in each of two secondary recipients, one of which was treated with, and responded to, AP1903. Our results demonstrate the feasibility of safely regulating genetically engineered hematopoietic cells over many years.

Poly(ADP-ribose) polymerase-1 (PARP-1) contributes to the barrier function of a vertebrate chromatin insulator.

The prototypic chromatin insulator cHS4 has proven effective in reducing silencing chromosomal position effects in a variety of settings. Most of this barrier insulator activity has been mapped to a 250-bp core region, as well as to several proteins that bind this region. However, recent studies from our laboratory demonstrated that an extended 400-bp core region of the cHS4 element is necessary to achieve full barrier insulator activity when used as a single copy in the context of recombinant gammaretroviral and lentiviral vectors. In this study, electrophoretic gel mobility shift assays revealed specific DNA-protein binding activities associated with the distal portion of this extended core region. Affinity purification and tandem mass spectrometry studies led to the identification of one of these proteins as poly(ADP-ribose) polymerase-1 (PARP-1). The identity of this binding activity as PARP-1 was subsequently verified by a variety of biochemical studies in vitro and by chromatin immunoprecipitation studies in vivo. Functional studies with gammaretroviral reporter vectors in cell lines and primary mouse bone marrow progenitor cultures showed that cHS4 barrier activity was abrogated upon mutation of the putative PARP-1-binding site or upon treatment with a PARP inhibitor, respectively. The barrier activity of the cHS4 element was also found to be abrogated in studies using bone marrow from Parp1-null mice. Taken together, this study demonstrates that binding of PARP-1 plays a key functional role in the barrier activity of the extended cHS4 insulator core element.

Novel therapeutic candidates, identified by molecular modeling, induce γ-globin gene expression in vivo.

The ß-hemoglobinopathies and thalassemias are serious genetic blood disorders affecting the ß-globin chain of hemoglobin A (α(2)ß(Α)(2)). Their clinical severity can be reduced by enhancing expression of fetal hemoglobin (γ-globin), producing HbF (α(2)γ(2,)). In studies reported here, γ-globin induction by 23 novel, structurally-unrelated compounds, which had been predicted through molecular modeling and in silico screening of a 13,000 chemical library, was evaluated in vitro in erythroid progenitors cultured from normal subjects and ß-thalassemia patients, and in vivo in transgenic mice or anemic baboons. Four predicted candidates were found to have high potency, with 4- to 8-fold induction of HbF. Two of these compounds have pharmacokinetic profiles favorable for clinical application. These studies thus effectively identified high potency γ-globin inducing candidate therapeutics and validated the utility of in silico molecular modeling.

Investigating the Barrier Activity of Novel, Human Enhancer-Blocking Chromatin Insulators for Hematopoietic Stem Cell Gene Therapy.

Despite the unequivocal success of hematopoietic stem and progenitor cell gene therapy, limitations still exist including genotoxicity and variegation/silencing of transgene expression. A class of DNA regulatory elements known as chromatin insulators (CIs) can mitigate both vector transcriptional silencing (barrier CIs) and vector-induced genotoxicity (enhancer-blocking CIs) and have been proposed as genetic modulators to minimize unwanted vector/genome interactions. Recently, a number of human, small-sized, and compact CIs bearing strong enhancer-blocking activity were identified. To ultimately uncover an ideal CI with a dual, enhancer-blocking and barrier activity, we interrogated these elements in vitro and in vivo. After initial screening of a series of these enhancer-blocking insulators for potential barrier activity, we identified three distinct categories with no, partial, or full protection against transgene silencing. Subsequently, the two CIs with full barrier activity (B4 and C1) were tested for their ability to protect against position effects in primary cells, after incorporation into lentiviral vectors (LVs) and transduction of human CD34+ cells. B4 and C1 did not adversely affect vector titers due to their small size, while they performed as strong barrier insulators in CD34+ cells, both in vitro and in vivo, shielding transgene's long-term expression, more robustly when placed in the forward orientation. Overall, the incorporation of these dual-functioning elements into therapeutic viral vectors will potentially provide a new generation of safer and more efficient LVs for all hematopoietic stem cell gene therapy applications.

Gene therapy for ß-thalassaemia: the continuing challenge.

The ß-thalassaemias are inherited anaemias that form the most common class of monogenic disorders in the world. Treatment options are limited, with allogeneic haematopoietic stem cell transplantation offering the only hope for lifelong cure. However, this option is not available for many patients as a result of either the lack of compatible donors or the increased risk of transplant-related mortality in subjects with organ damage resulting from accumulated iron. The paucity of alternative treatments for patients that fall into either of these categories has led to the development of a revolutionary treatment strategy based on gene therapy. This approach involves replacing allogeneic stem cell transplantation with the transfer of normal globin genes into patient-derived, autologous haematopoietic stem cells. This highly attractive strategy offers several advantages, including bypassing the need for allogeneic donors and the immunosuppression required to achieve engraftment of the transplanted cells and to eliminate the risk of donor-related graft-versus-host disease. This review discusses the many advances that have been made towards this endeavour as well as the hurdles that must still be overcome before gene therapy for ß-thalassaemia, as well as many other gene therapy applications, can be widely applied in the clinic.

A functional screen for regulatory elements that improve retroviral vector gene expression.

Recombinant retroviruses constitute the most common class of gene delivery vectors used in hematopoietic cell-based gene therapy. However, the use of these vectors can be limited by inadequate levels of transgene expression, often mediated by expression variegation and vector silencing due to chromosomal position effects. Toward the goal of addressing this problem, we sought to identify cis-regulatory elements from the human genome that can improve the level and stability of retroviral vector gene expression. Libraries of size-selected fragments from the human genome were cloned into the "double-copy" position of the gammaretroviral reporter vector MGPN2, and the resulting vectors underwent several rounds of transduction and selection for high-level vector GFP expression. From this screen we identified both enhancer-like elements and vector mutations associated with increased vector expression. One element, H-11, exhibited enhancer activity in a mouse bone marrow progenitor colony assay, a human promoter trap assay, and a long-term mouse bone marrow transplant assay. This element seems to be an orientation-dependent, tissue-independent enhancer.

Genomic and functional assays demonstrate reduced gammaretroviral vector genotoxicity associated with use of the cHS4 chromatin insulator.

Interest in the use of recombinant retroviral vectors for clinical gene therapy has been tempered by evidence of vector-mediated genotoxicity involving the activation of cellular oncogenes flanking sites of vector integration. We report here that the rate of gammaretroviral vector genotoxicity can be significantly reduced by addition of the cHS4 chromatin insulator, based on two complementary approaches for assessing vector-mediated genotoxicity. One approach involves the direct, genomewide assessment of cellular gene dysregulation using panels of transduced cell clones and genomic microarrays, whereas the other involves the functional assessment of malignant transformation using a factor-dependent cell line. Both assays are robust and quantitative, and indicate the cHS4 chromatin insulator can reduce vector-mediated genotoxicity approximately sixfold (ranged three to eight fold). These approaches also provide a means for assessing various aspects of vector-mediated genotoxicity, including the overall rate of cellular gene dysregulation, the potential influence of vector provirus over large genomic distances, and the involvement of oncogenic pathways in vector-mediated malignant transformation.

Extended core sequences from the cHS4 insulator are necessary for protecting retroviral vectors from silencing position effects.

The prototypic chromatin insulator cHS4 has proven effective at reducing repressive chromosomal position effects on retroviral vector expression. We report here studies designed to identify the minimal chicken hypersensitive site-4 (cHS4) sequences necessary for this activity. Using a gammaretroviral reporter vector and expression analysis in cell lines and primary mouse hematopoietic progenitor colonies, we found that a 250-bp core fragment reported to contain most of the cHS4 insulating activity failed to prevent silencing when used alone, although some barrier activity was observed when this fragment was combined with a 790-bp, but not 596-bp, spacer. Similar studies showed that four copies of a 90-bp fragment containing the cHS4 enhancer-blocking activity actually repressed vector green fluorescent protein (GFP) expression. In contrast, a 400-bp fragment containing the 250-bp core plus 3' flanking sequences protected vector expression to the same degree as the full-length 1.2-kb fragment. The 400-bp fragment activity was confirmed in a lentiviral vector expressing human beta-globin in murine erythroid leukemia (MEL) cells. Taken together, these studies indicate that the insulating activity of the 250-bp cHS4 core can be influenced by distance, and identify an extended core element that confers full barrier activity in the setting of two different classes of retroviral vectors.

Simultaneous sequence transfer into two independent locations of a reporter vector using MultiSite Gateway technology.

The bacteriophage lambda recombination system is increasingly used for recombinant DNA applications that involve the frequent transfer of sequences into and between shuttle and reporter vectors. This approach bypasses the need for restriction endonucleases or ligases and, as such, is easily scalable and automated. However this system has not yet been tested for the ability to support the simultaneous introduction of donor fragments into two separate target sites of a single reporter plasmid. This attribute would greatly facilitate studies of cis-regulatory elements that only function in specific combinations, such as a class of regulatory elements known as chromatin insulators. With the goal of facilitating a screen for chromatin insulators, we sought to determine whether the commercially available MultiSite Gateway Technology recombination system could be used to simultaneously insert candidate insulator elements into two separate locations of a functional reporter plasmid. We show that this application is both highly efficient and specific, generating the desired recombination products nearly three quarters of the time without disrupting the specificity of the reporter system. As such, these studies establish a novel application of the MultiSite Gateway Technology for the generation of recombinant reporter plasmids where the constituent elements function in a combinatorial fashion.

Use of CD9 expression to enrich for porcine hematopoietic progenitors.

OBJECTIVE: The aim of this study was to develop novel markers for enrichment of hematopoietic progenitors from bone marrow of swine. MATERIALS AND METHODS: We previously showed that pig bone marrow contains a "side population" (SP) of Hoechst dye-effluxing cells that resembles the hematopoietic stem cell (HSC)-containing murine SP and therefore represents a putative pig stem cell population. We screened a panel of monoclonal antibodies for those that allowed positive or negative enrichment of porcine SP cells and tested one of these for enrichment of hematopoietic progenitors in short-term and long-term in vitro assays. We then screened an expression library to clone the gene whose product is recognized by this antibody. RESULTS: Among a panel of 35 monoclonal lines screened, we found three that were useful for positive enrichment of SP cells and seven for negative enrichment. The 4-6 monoclonal line, allowing around 10-fold negative enrichment of SP cells, recognized the product of the porcine CD9 gene. Hematopoietic progenitors measured by short-term colony-forming unit and long-term cobblestone area-forming cell assays were around 10-fold enriched in the CD9(negative/low) fraction and were significantly depleted in the CD9(high) fraction. CONCLUSIONS: The antibody against the porcine CD9 gene product may be of use for enrichment of porcine hematopoietic stem cells. This approach to identify novel markers for enrichment of hematopoietic progenitors may be applicable to other mammalian species.

Functional validation of a constitutive autonomous silencer element.

Sequences of the genome that are capable of silencing gene expression are thought to play a key role in gene regulation. However, very few silencer elements capable of functioning in mammalian cells have been described, and only a fraction of these have been tested for the ability to function in an autonomous fashion. We report here the characterization and functional validation of a constitutive autonomous silencer element from the human genome called T39, and the comparison of T39 to three other putative silencer elements previously described by others. Functional analysis included one assay for enhancer-blocking insulator activity and two independent assays for silencer activity, all based on stable transfection and comparison to a neutral spacer control. In erythroid K562 cells, T39 exhibited potent silencer activity, the previously described element PRE2-S5 exhibited modest silencer activity, and the two other previously described elements exhibited no silencer activity. T39 was further found to be capable of silencing three disparate promoters, of silencing gene expression in three disparate cell lines, and of functioning as a single copy in a topology-independent manner. Of the four elements analyzed, only T39 exhibits a constitutive pattern of DNase hypersensitivity and binding by CTCF. In its native location the T39 element also exhibits a unique interaction profile with a subset of distal putative regulatory elements. Taken together, these studies validate T39 as a constitutive autonomous silencer, identify T39 as a defined control for future studies of other regulatory elements such as insulators, and provide a basic chromatin profile for one highly potent silencer element.

Genomic discovery of potent chromatin insulators for human gene therapy.

Insertional mutagenesis and genotoxicity, which usually manifest as hematopoietic malignancy, represent major barriers to realizing the promise of gene therapy. Although insulator sequences that block transcriptional enhancers could mitigate or eliminate these risks, so far no human insulators with high functional potency have been identified. Here we describe a genomic approach for the identification of compact sequence elements that function as insulators. These elements are highly occupied by the insulator protein CTCF, are DNase I hypersensitive and represent only a small minority of the CTCF recognition sequences in the human genome. We show that the elements identified acted as potent enhancer blockers and substantially decreased the risk of tumor formation in a cancer-prone animal model. The elements are small, can be efficiently accommodated by viral vectors and have no detrimental effects on viral titers. The insulators we describe here are expected to increase the safety of gene therapy for genetic diseases.

Hematopoietic stem cell gene therapy.

Gene therapy applications that target hematopoietic stem cells (HSCs) offer great potential for the treatment of hematologic disease. Despite this promise, clinical success has been limited by poor rates of gene transfer, poor engraftment of modified cells, and poor levels of gene expression. We describe here the basic approach used for HSC gene therapy, briefly review some of the seminal clinical trials in the field, and describe several recent advances directed toward overcoming these limitations.

Identification and characterization of enhancer-blocking insulators to reduce retroviral vector genotoxicity.

The chromatin insulator cHS4 can reduce silencing chromosomal position effects and genotoxicity associated with integrating viral vectors. However, the fully active version of this element can also reduce vector titers and is only partially effective. In order to identify alternatives to cHS4, we developed a functional lentiviral vector-based reporter screen for enhancer-blocking insulators. Using this system, we screened candidate sequences that were initially identified by chromatin profiling for binding by CTCF and for DNase hypersensitivity. All 12 analyzed candidates blocked enhancer-promoter activity. The enhancer-blocking activity of the top two candidates was confirmed in two complementary plasmid-based assays. Studies in a gammaretroviral reporter vector indicated these two candidates have little to no effect on vector titers, and do not diminish vector expression in primary mouse bone marrow cultures. Subsequent assessment in a mouse in vivo tumor formation model demonstrated that both candidates reduced the rate of gammaretroviral vector-mediated genotoxicity as effectively as the cHS4 insulator. In summary, we have developed a novel lentiviral vector-based method of screening candidate elements for insulator activity, and have used this method to identify two new insulator elements capable of improving the safety of retroviral vectors without diminishing vector titers or expression. These findings expand the limited arsenal of insulators functionally validated to reduce the rate of retroviral vector-mediated genotoxicity.

Gammaretroviral vector integration occurs overwhelmingly within and near DNase hypersensitive sites.

Concerns surrounding the oncogenic potential of recombinant gammaretroviral vectors has spurred a great deal of interest in vector integration site (VIS) preferences. Although gammaretroviral vectors exhibit a modest preference for integration near transcription start sites (TSS) of active genes, such associations only account for about a third of all VIS. Previous studies suggested a correlation between gammaretroviral VIS and DNase hypersensitive sites (DHS), which mark chromatin regions associated with cis-regulatory elements. In order to study this issue directly, we assessed the correlation between 167 validated gammaretroviral VIS and a deep genome-wide map of DHS, both determined in the same cell line (the human fibrosarcoma HT1080). The DHS map was developed by sequencing individual DNase I cleavage sites using massively parallel sequencing technologies. These studies revealed an overwhelming preference for integrations associated with DHS, with a median distance of only 238 bp between individual VIS and the nearest DHS for the experimental dataset, compared to 3 kb for a random dataset and 577 to 1457 bp for two unrelated cell lines (p<0.001). Indeed, nearly 84% of all VIS were found to be located within 1 kb of a DHS (p=10(-43)). Further, this correlation was statistically independent from the association with TSS. The preference for DHS far exceeds that seen for other hallmarks of gammaretroviral VIS, including TSS, and may help explain several aspects of gammaretroviral vector biology, including the mechanism of VIS selection, as well as the relative frequency and underlying biology of gammaretroviral vector-mediated genotoxicity.