Generation of multipurpose alleles for the functional analysis of the mouse genome.

A novel generation of retroviral gene-trap vectors has been developed with the ability to induce conditional mutations in most genes expressed in mouse embryonic stem (ES) cells. The vectors rely on directional site-specific recombination systems, which can repair and re-induce the gene-trap mutations when activated in succession. After the gene-trap insertions are passaged into mice, this system enables the induction of temporally and spatially restricted mutations in somatic cells. In addition to their conditional features, the vectors create multipurpose alleles amenable to a wide range of post-insertional modifications. These vectors have been used to assemble the largest library of ES cell lines with conditional mutations in single genes, presently totalling 1724 unique genes. Due to their efficiency, the vectors are part of the core technologies to be used by EUCOMM for establishing a complete collection of conditional null mutations in mice.     

Gene trapping of the Arabidopsis genome with a firefly luciferase reporter

Experiments with gene-trap vectors containing the firefly luciferase (LUC) reporter genes were carried out with the aim of analyzing functions of the Arabidopsis genome. Studies with protein fusion-type trap vectors as well as an internal ribosome entry site (IRES)-assisted non-fusion-type vector revealed that both types of vectors were suitable for gene trapping in Arabidopsis, although there were some differences in trapping efficiencies. The established trap lines were subjected to analyses for light responses, demonstrating the powerful and unique applications of a LUC-trapping system. A systematic survey of the insertion sites of the T-DNAs in LUC-expressing lines revealed 12-41% gene-trapping efficiencies depending on the vector. We demonstrate that the LUC-trapping system provides a unique system with which to monitor temporal expression of plant genes.     

Targeted gene modification in mouse ES cells using integrase‐defective lentiviral vectors

Lentiviral vectors efficiently integrate into the host genome of both dividing and nondividing cells, and so they have been used for stable transgene expression in biological and biomedical studies. However, recent studies have highlighted the risk of insertional mutagenesis and subsequent oncogenesis. Here, we used an integrase‐defective lentiviral (IDLV) vector to decrease the chance of random integration and examined the feasibility of lentiviral vector‐mediated gene targeting into murine embryonic stem (ES) cells. After transduction with wild‐type lentiviral vectors, none of the 512 G418 resistant clones were found to be homologous recombinant clones. Although the transduction efficiency was lower with the IDLV vectors (5.9% of wild‐type), successful homologous recombination was observed in nine out of the 941 G418 resistant clones (0.83 ± 1.32%). Pluripotency of the homologous recombinant ES cells was confirmed by the production of chimeric mice and subsequent germ line transmission. Because lentiviral vectors can efficiently transduce a variety of stem cell types, our strategy has potential relevance for secure gene‐manipulation in therapeutic applications. genesis 47:217–223, 2009. © 2009 Wiley‐Liss, Inc.     

Hematopoietic stem cell gene transfer in a tumor-prone mouse model uncovers low genotoxicity of lentiviral vector integration

Insertional mutagenesis represents a major hurdle to gene therapy and necessitates sensitive preclinical genotoxicity assays. Cdkn2a-/- mice are susceptible to a broad range of cancer-triggering genetic lesions. We exploited hematopoietic stem cells from these tumor-prone mice to assess the oncogenicity of prototypical retroviral and lentiviral vectors. We transduced hematopoietic stem cells in matched clinically relevant conditions, and compared integration site selection and tumor development in transplanted mice. Retroviral vectors triggered dose-dependent acceleration of tumor onset contingent on long terminal repeat activity. Insertions at oncogenes and cell-cycle genes were enriched in early-onset tumors, indicating cooperation in tumorigenesis. In contrast, tumorigenesis was unaffected by lentiviral vectors and did not enrich for specific integrants, despite the higher integration load and robust expression of lentiviral vectors in all hematopoietic lineages. Our results validate a much-needed platform to assess vector safety and provide direct evidence that prototypical lentiviral vectors have low oncogenic potential, highlighting a major rationale for application to gene therapy.     

Lentiviral and MLV based retroviral vectors for ex vivo and in vivo gene transfer

Retroviral vectors have become an important tool for gene transfer in vitro and in vivo. Classical Moloney murine leukemia virus (MLV) based retroviral vectors have been used for over 20 years to transfer genes into dividing cells. Cell lines for production of retroviral vectors have become commonly available and modifications in retroviral vector design and use of envelope proteins have made the production of high titer, helper-free, infectious virus stocks relatively easy. More recently, lentiviral vectors, another class of retroviruses, have been modified for in vitro and in vivo gene transfer. The ability of lentiviral vectors to transduce non-dividing cells has made them especially attractive for in vivo gene transfer into differentiated, non-dividing tissues. Several improvements in helper plasmids and vectors have made lentivirus a safe vector system for ex vivo and in vivo gene transfer. This review will briefly summarize the background of these vector systems and provide some common protocols available for the preparation of MLV based retroviral vectors and HIV-1 based lentiviral vectors.     

In Vivo Assessment of Gene Delivery to Keratinocytes by Lentiviral Vectors

For skin gene therapy, introduction of a desired gene into keratinocyte progenitor or stem cells could overcome the problem of achieving persistent gene expression in a significant percentage of keratinocytes. Although keratinocyte stem cells have not yet been completely characterized and purified for gene targeting purposes, lentiviral vectors may be superior to retroviral vectors at gene introduction into these stem cells, which are believed to divide and cycle slowly. Our initial in vitro studies demonstrate that lentiviral vectors are able to efficiently transduce nondividing keratinocytes, unlike retroviral vectors, and do not require the lentiviral accessory genes for keratinocyte transduction. When lentiviral vectors expressing green fluorescent protein (GFP) were directly injected into the dermis of human skin grafted onto immunocompromised mice, transduction of dividing basal and nondividing suprabasal keratinocytes could be demonstrated, which was not the case when control retroviral vectors were used. However, flow cytometry analysis demonstrated low transduction efficiency, and histological analysis at later time points provided no evidence for progenitor cell targeting. In an alternative in vivo method, human keratinocytes were transduced in tissue culture (ex vivo) with either lentiviral or retroviral vectors and grafted as skin equivalents onto immunocompromised mice. GFP expression was analyzed in these human skin grafts after several cycles of epidermal turnover, and both the lentiviral and retroviral vector-transduced grafts had similar percentages of GFP-expressing keratinocytes. This ex vivo grafting study provides a good in vivo assessment of gene introduction into progenitor cells and suggests that lentiviral vectors are not necessarily superior to retroviral vectors at introducing genes into keratinocyte progenitor cells during in vitro culture.     

A high throughput method for genome-wide analysis of retroviral integration

Retroviral and lentiviral vectors integrate their DNA into the host cell genome leading to stable transgene expression. Integration preferentially occurs in the proximity of active genes, and may in some case disturb their activity, with adverse toxic consequences. To efficiently analyze high numbers of lentiviral insertion sites in the DNA of transduced cells, we developed an improved high-throughput method called vector integration tag analysis (VITA). VITA is based on the identification of Genomic Tags associated to the insertion sites, which are used as signatures of the integration events. We use the capacity of MmeI to cleave DNA at a defined distance of its recognition site, in order to generate 21 bp long tags from libraries of junction fragments between vector and cellular DNA. The length of the tags is sufficient in most cases, to identify without ambiguity an unique position in the human genome. Concatenation, cloning and sequencing of the tags allow to obtain information about 20–25 insertion sites in a single sequencing reaction. As a validation of this method, we have characterized 1349 different lentiviral vector insertion sites in transduced HeLa cells, from only 487 sequencing reactions, with a background of <2% false positive tags.     

Lentiviral vectors: basic to translational

More than two decades have passed since genetically modified HIV was used for gene delivery. Through continuous improvements these early marker gene-carrying HIVs have evolved into safer and more effective lentiviral vectors. Lentiviral vectors offer several attractive properties as gene-delivery vehicles, including: (i) sustained gene delivery through stable vector integration into host genome; (ii) the capability of infecting both dividing and non-dividing cells; (iii) broad tissue tropisms, including important gene- and cell-therapy-target cell types; (iv) no expression of viral proteins after vector transduction; (v) the ability to deliver complex genetic elements, such as polycistronic or intron-containing sequences; (vi) potentially safer integration site profile; and (vii) a relatively easy system for vector manipulation and production. Accordingly, lentivector technologies now have widespread use in basic biology and translational studies for stable transgene overexpression, persistent gene silencing, immunization, in vivo imaging, generating transgenic animals, induction of pluripotent cells, stem cell modification and lineage tracking, or site-directed gene editing. Moreover, in the present high-throughput '-omics' era, the commercial availability of premade lentiviral vectors, which are engineered to express or silence genome-wide genes, accelerates the rapid expansion of this vector technology. In the present review, we assess the advances in lentiviral vector technology, including basic lentivirology, vector designs for improved efficiency and biosafety, protocols for vector production and infection, targeted gene delivery, advanced lentiviral applications and issues associated with the vector system.     

Gene-trap mutagenesis using Mol/MSM-1 embryonic stem cells from MSM/Ms mice

The MSM/Ms strain is derived from the Japanese wild mouse Mus musculus molossinus and displays characteristics not observed in common laboratory strains. Functional genomic analyses using genetically engineered MSM/Ms mice will reveal novel phenotypes and gene functions/interactions. We previously reported the establishment of a germline-competent embryonic stem (ES) cell line, Mol/MSM-1, from the MSM/Ms strain. To analyze its usefulness for insertional mutagenesis, we performed gene-trapping using these cells. In the present study, we compared the gene-trap events between Mol/MSM-1 and a conventional ES cell line, KTPU8, derived from the F1 progeny of a C57BL/6 × CBA cross. We introduced a promoter-trap vector carrying the promoterless β-galactosidase/neomycin-resistance fusion gene into Mol/MSM-1 and KTPU8 cells, isolated clones, and identified the trapped genes by rapid amplification of cDNA 5′-ends (5′-RACE), inverse PCR, or plasmid rescue. Unexpectedly, the success rate of 5′-RACE in Mol/MSM trap clones was 47 %, lower than the 87 % observed in KTPU8 clones. Genomic analysis of the 5′-RACE-failed clones revealed that most had trapped ribosomal RNA gene regions. The percentage of ribosomal RNA region trap clones was 41 % in Mol/MSM-1 cells, but less than 10 % in KTPU8 cells. However, within the Mol/MSM-1 5′-RACE-successful clones, the trapping frequency of annotated genes, the chromosomal distribution of vector insertions, the frequency of integration into an intron around the start codon-containing exon, and the functional spectrum of trapped genes were comparable to those in KTPU8 cells. By selecting 5′-RACE-successful clones, it is possible to perform gene-trapping efficiently using Mol/MSM-1 ES cells and promoter-trap vectors.     

Construction of Retroviral Vectors with Improved Safety, Gene Expression, and Versatility

Murine leukemia virus (MLV)-based retroviral vectors are the most frequently used gene delivery vehicles. However, the current vectors are still not fully optimized for gene expression and viral titer, and many genetic and biochemical features of MLV-based vectors are poorly understood. We have previously reported that the retroviral vector MFG, where the gene of interest is expressed as a spliced mRNA, is superior in the level of gene expression with respect to other vectors compared in the study. As one approach to developing improved retroviral vectors, we have systematically performed mutational analysis of the MFG retroviral vector. We demonstrated that the entire gag coding sequence, together with the immediate upstream region, could be deleted without significantly affecting viral packaging or gene expression. To our knowledge, this region is included in all currently available retroviral vectors. In addition, almost the entire U3 region could be replaced with the heterologous human cytomegalovirus immediately-early promoter without deleterious effects. We could also insert internal ribosome entry sites (IRES) and multicloning sites into MFG without adverse effects. Based on these observations, we have constructed a series of new, improved retroviral constructs. These vectors produced viral titers comparable to MFG, expressed high levels of gene expression, and stably transferred genes to the target cells. Our vectors are more convenient to use because of the presence of multicloning sites and IRESs, and they are also more versatile because they can be readily converted to various applications. Our results have general implications regarding the design and development of improved retroviral vectors for gene therapy.