An efficient in vitro transposition method by a transcriptionally regulated sleeping beauty system packaged into an integration defective lentiviral vector

The Sleeping Beauty (SB) transposon is a non-viral integrating system with proven efficacy for gene transfer and functional genomics. To optimize the SB transposon machinery, a transcriptionally regulated hyperactive transposase (SB100X) and T2-based transposon are employed. Typically, the transposase and transposon are provided transiently by plasmid transfection and SB100X expression is driven by a constitutive promoter. Here, we describe an efficient method to deliver the SB components to human cells that are resistant to several physical and chemical transfection methods, to control SB100X expression and stably integrate a gene of interest (GOI) through a "cut and paste" SB mechanism. The expression of hyperactive transposase is tightly controlled by the Tet-ON system, widely used to control gene expression since 1992. The gene of interest is flanked by inverted repeats (IR) of the T2 transposon. Both SB components are packaged in integration defective lentiviral vectors transiently produced in HEK293T cells. Human cells, either cell lines or primary cells from human tissue, are in vitro transiently transduced with viral vectors. Upon addition of doxycycline (dox, tetracycline analog) into the culture medium, a fine-tuning of transposase expression is measured and results in a long-lasting integration of the gene of interest in the genome of the treated cells. This method is efficient and applicable to the cell line (e.g., HeLa cells) and primary cells (e.g., human primary keratinocytes), and thus represents a valuable tool for genetic engineering and therapeutic gene transfer

Design of a regulated lentiviral vector for hematopoietic stem cell gene therapy of globoid cell leukodystrophy

Globoid cell leukodystrophy (GLD) is a demyelinating lysosomal storage disease due to the deficiency of the galactocerebrosidase (GALC) enzyme. The favorable outcome of hematopoietic stem and progenitor cell (HSPC)-based approaches in GLD and other similar diseases suggests HSPC gene therapy as a promising therapeutic option for patients. The path to clinical development of this strategy was hampered by a selective toxicity of the overexpressed GALC in the HSPC compartment. Here, we presented the optimization of a lentiviral vector (LV) in which miR-126 regulation was coupled to codon optimization of the human GALC cDNA to obtain a selective and enhanced enzymatic activity only upon transduced HSPCs differentiation. The safety of human GALC overexpression driven by this LV was extensively demonstrated in vitro and in vivo on human HSPCs from healthy donors. No perturbation in the content of proapoptotic sphingolipids, gene expression profile, and capability of engraftment and mutlilineage differentiation in chimeric mice was observed. The therapeutic potential of this LV was then assessed in a severe GLD murine model that benefited from transplantation of corrected HSPCs with longer survival and ameliorated phenotype as compared to untreated siblings. This construct has thus been selected as a candidate for clinical translatio

CRISPR/Cas9-Mediated In Situ Correction of LAMB3 Gene in Keratinocytes Derived from a Junctional Epidermolysis Bullosa Patient

Deficiency of basement membrane heterotrimeric laminin 332 component, coded by LAMA3, LAMB3, and LAMC2 genes, causes junctional epidermolysis bullosa (JEB), a severe skin adhesion defect. Herein, we report the first application of CRISPR/Cas9-mediated homology direct repair (HDR) to in situ restore LAMB3 expression in JEB keratinocytes in vitro and in immunodeficient mice transplanted with genetically corrected skin equivalents. We packaged an adenovector carrying Cas9/guide RNA (gRNA) tailored to the intron 2 of LAMB3 gene and an integration defective lentiviral vector bearing a promoterless quasi-complete LAMB3 cDNA downstream a splice acceptor site and flanked by homology arms. Upon genuine HDR, we exploited the in vitro adhesion advantage of laminin 332 production to positively select LAMB3-expressing keratinocytes. HDR and restored laminin 332 expression were evaluated at single-cell level. Notably, monoallelic-targeted integration of LAMB3 cDNA was sufficient to in vitro recapitulate the adhesive property, the colony formation typical of normal keratinocytes, as well as their cell growth. Grafting of genetically corrected skin equivalents onto immunodeficient mice showed a completely restored dermal-epidermal junction. This study provides evidence for efficient CRISPR/Cas9-mediated in situ restoration of LAMB3 expression, paving the way for ex vivo clinical application of this strategy to laminin 332 deficiency

High-Definition Mapping of Retroviral Integration Sites Defines the Fate of Allogeneic T Cells After Donor Lymphocyte Infusion

The infusion of donor lymphocytes transduced with a retroviral vector expressing the HSV-TK suicide gene in patients undergoing hematopoietic stem cell transplantation for leukemia/lymphoma promotes immune reconstitution and prevents infections and graft-versus-host disease. Analysis of the clonal dynamics of genetically modified lymphocytes in vivo is of crucial importance to understand the potential genotoxic risk of this therapeutic approach. We used linear amplification-mediated PCR and pyrosequencing to build a genome-wide, high-definition map of retroviral integration sites in the genome of peripheral blood T cells from two different donors and used gene expression profiling and bioinformatics to associate integration clusters to transcriptional activity and to genetic and epigenetic features of the T cell genome. Comparison with matched random controls and with integrations obtained from CD34+ hematopoietic stem/progenitor cells showed that integration clusters occur within chromatin regions bearing epigenetic marks associated with active promoters and regulatory elements in a cell-specific fashion. Analysis of integration sites in T cells obtained ex vivo two months after infusion showed no evidence of integration-related clonal expansion or dominance, but rather loss of cells harboring integration events interfering with RNA post-transcriptional processing. The study shows that high-definition maps of retroviral integration sites are a powerful tool to analyze the fate of genetically modified T cells in patients and the biological consequences of retroviral transduction

Hoxd13 binds in vivo and regulates the expression of genes acting in key pathways for early limb and skeletal patterning.

5' HoxD genes are required for the correct formation of limb skeletal elements. Hoxd13, the most 5'-located HoxD gene, is important for patterning the most distal limb region, and its mutation causes human limb malformation syndromes. The mechanisms underlying the control of developmental processes by Hoxd13, and by Hox genes in general, are still elusive, due to the limited knowledge on their direct downstream target genes. We identified by ChIP-on-chip 248 known gene loci bound invivo by Hoxd13. Genes relevant to limb patterning and skeletogenesis were further analysed. We found that Hoxd13 binds invivo, in developing limbs, the loci of Hand2, a gene crucial to limb AP axis patterning, of Meis1 and Meis2, involved in PD patterning, of the Sfrp1, Barx1, and Fbn1 genes, involved in skeletogenesis, and of the Dach1, Bmp2, Bmp4, andEmx2 genes. We show that Hoxd13 misexpression in developing chick limbs alters the expression of the majority of these genes, supporting the conclusion that Hoxd13 directly regulates their transcription. Our results indicate that 5' Hox proteins regulate directly both key genes for early limb AP and PD axis patterning and genes involved, at later stages, in skeletal patterning

Non viral gene transfer via Sleeping beauty transposon for Collagen VII delivery in human primary keratinocytes.

Autosomal recessive epidermolysis bullosa (RDEB) is a genetic skin adhesion defect caused by mutations in the type VII collagen gene (COL7A1). Although full-length type-VII collagen is successfully produced in human keratinocytes by retroviral vectors, genetic instability due to the large size (9kb) and the highly repeated nature of the gene sequence is a persistent problem. The Sleeping-Beauty (SB) transposon-based integration system can potentially overcome these issues by taking advantage of the hyperactive SB100X transposase in combination with the wild-type (pT2) transposon or the “sandwich” version (pSA) that showed robust transposition efficiency in human cells. We molecularly characterized the “sandwich” SB-mediated integrants in epithelial cell lines and in primary keratinocytes. Co-transfecting the transposase together with 10kb-transposon (pT2 or pSA) we observed up to 37% of transposition in HaCaT and in GABEB (generalized atrophic benign epidermolysis bullosa keratinocytes) cells with both transposons. Clonal analysis demonstrated that the transposition events occur with a minimal risk of rearrangements (<3%). LM-PCR based bi-directional sequencing of the transposon-genome junctions shows genuine “cut and paste” activity of the SB hyperactive transposase

In vitro and in vivo CRISPR/Cas9-mediated genome editing to downregulate dominant mutations in Rhodopsin gene

Many progresses have been made in understanding the genetic basis for Retinitis Pigmentosa (RP), however therapeutic interventions are still lagging behind. Rhodopsin (RHO) mutations represent a common cause of RP, accounting for 25% of autosomal dominant RP and 8-10% of all RP (Hartong et al., 2006) with more than 100 different mutations identified so far. Here we show the application of CRISPR-Cas9 technology to knock out the RHO defective alleles by introducing double strand breaks into the target gene. We designed single or double gRNAs to knock-down mutant RHO expression by targeting exon 1 of the RHO gene carrying the P23H dominant mutation. The two gRNAs were tested singularly or together in vitro in HeLa clones stably expressing P23H RHO. Cel I assay, TIDE and sequencing analyses demonstrated insertions or deletions (indels) in the genomic DNA specifically in the RHO gene, which caused strong reduction of RHO expression up to 90%. The higher effect was obtained with two gRNAs together. The CRISPR/Cas9 plasmid expressing two gRNAs were then in vivo tested in P23H RHO transgenic mice by sub-retinal electroporation, together with EGFP expressing plasmids. Analysis of indels in FACS-sorted EGFP+ cells demonstrated up to 30% of in vivo genome editing of the human P23H RHO gene, without targeting of the murine Rho allele. We also detected reduction of RHO at mRNA and protein levels. Thus, successful in vivo application of the CRISPR/Cas9 system confirms its efficacy as a genetic engineering tool and its potential use in gene therapy

Transcriptionally regulated and nontoxic delivery of the hyperactive Sleeping Beauty Transposase

The Sleeping Beauty (SB) transposase and, in particular, its hyperactive variant SB100X raises increasing interest for gene therapy application, including genome modification and, more recently, induced pluripotent stem cells (iPS) reprogramming. The documented cytotoxicity of the transposase, when constitutively expressed by an integrating retroviral vector (iRV), has been circumvented by the transient delivery of SB100X using retroviral mRNA transfer. In this study, we developed an alternative, safe, and efficient transposase delivery system based on a tetracycline-ON regulated expression cassette and the rtTA2S-M2 transactivator gene transiently delivered by integration-defective lentiviral vectors (IDLVs). Compared with iRV-mediated delivery, expression of tetracycline-induced SB100X delivered by an IDLV results in more efficient integration of a GFP transposon and reduced toxicity. Tightly regulated expression and reactivation of the transposase was achieved in HeLa cells as wells as in human primary keratinocytes. Based on these properties, the regulated transposase-IDLV vectors may represent a valuable tool for genetic engineering and therapeutic gene transfer