Project description:Gene transfer vectors may cause clonal imbalance and even malignant cell transformation by insertional upregulation of proto-oncogenes. Lentiviral vectors (LV) with their preferred integration in transcribed genes are considered less genotoxic than gammaretroviral vectors (GV) with their preference for integration next to transcriptional start sites and regulatory gene regions. Using a sensitive cell culture assay and a series of self-inactivating (SIN) vectors, we found that the lentiviral insertion pattern was approximately threefold less likely than the gammaretroviral to trigger transformation of primary hematopoietic cells. However, lentivirally induced mutants also showed robust replating, in line with the selection for common insertion sites (CIS) in the first intron of the Evi1 proto-oncogene. This potent proto-oncogene thus represents a CIS for both GV and LV, despite major differences in their integration mechanisms. Altering the vectors' enhancer-promoter elements had a greater effect on safety than the retroviral insertion pattern. Clinical grade LV expressing the Wiskott-Aldrich syndrome (WAS) protein under control of its own promoter had no transforming potential. Mechanistic studies support the conclusion that enhancer-mediated gene activation is the major cause for insertional transformation of hematopoietic cells, opening rational strategies for risk prevention.

Project description:Replication-incompetent gammaretroviral (?RV) and lentiviral (LV) vectors have both been used in insertional mutagenesis screens to identify cancer drivers. In this approach the vectors stably integrate in the host cell genome and induce cancers by dysregulating nearby genes. The cells that contain a retroviral vector provirus in or near a proto-oncogene or tumor suppressor are preferentially enriched in a tumor. ?RV and LV vectors have different integration profiles and genotoxic potential, making them potentially complementary tools for insertional mutagenesis screens. We performed screens using both ?RV and LV vectors to identify driver genes that mediate progression of androgen-independent prostate cancer (AIPC) using a xenotransplant mouse model. Vector transduced LNCaP cells were injected orthotopically into the prostate gland of immunodeficient mice. Mice that developed tumors were castrated to create an androgen-deficient environment and metastatic tumors that developed were analyzed. A high-throughput modified genomic sequencing PCR (MGS-PCR) approach identified the positions of vector integrations in these metastatic tumors. OR2A14, FER1L6, TAOK3, MAN1A2, MBNL2, SERBP1, PLEKHA2, SPTAN1, ADAMTS1, SLC30A5, ABCC1, SLC7A1 and SLC25A24 were identified as candidate prostate cancer (PC) progression genes. TAOK3 and ABCC1 expression in PC patients predicted the risk of recurrence after androgen deprivation therapy. Our data shows that ?RV and LV vectors are complementary approaches to identify cancer driver genes which may be promising potential biomarkers and therapeutic targets.

Project description:Despite significant improvements in lentivirus (LV) vector-based gene therapy there are still several safety risks using LV vectors including the potential formation of replication-competent LV particles. To address this shortcoming, we constructed a novel and safer gene transfer system using modified SIN-based LV gene transfer vectors. Central to our approach is a conditional deletion of the ? packaging signal after integration in the target genome. Here we demonstrate that after transduction of target cells, conventional SIN-based LV transfer vectors can still be mobilized. However mobilization is rendered undetectable if transductions are followed by a Cre/loxP-mediated excision of ?. Thus conditional elimination of the packaging signal may represent another advance in increasing the safety of LV vectors for gene therapeutic treatment of chronic diseases.

Project description:This review offers the basics of lentiviral vector technologies, their advantages and pitfalls, and an overview of their use in the field of ophthalmology. First, the description of the global challenges encountered to develop safe and efficient lentiviral recombinant vectors for clinical application is provided. The risks and the measures taken to minimize secondary effects as well as new strategies using these vectors are also discussed. This review then focuses on lentiviral vectors specifically designed for ocular therapy and goes over preclinical and clinical studies describing their safety and efficacy. A therapeutic approach using lentiviral vector-mediated gene therapy is currently being developed for many ocular diseases, e.g., aged-related macular degeneration, retinopathy of prematurity, inherited retinal dystrophies (Leber congenital amaurosis type 2, Stargardt disease, Usher syndrome), glaucoma, and corneal fibrosis or engraftment rejection. In summary, this review shows how lentiviral vectors offer an interesting alternative for gene therapy in all ocular compartments.

Project description:Genetic modification of T lymphocytes is a key issue in research and therapy. Conventional lentiviral vectors (LVs) are neither selective for T cells nor do they modify resting or minimally stimulated cells, which is crucial for applications, such as efficient in vivo modification of T lymphocytes. Here, we introduce novel CD3-targeted LVs (CD3-LVs) capable of genetically modifying human T lymphocytes without prior activation. For CD3 attachment, agonistic CD3-specific single-chain variable fragments were chosen. Activation, proliferation, and expansion mediated by CD3-LVs were less rapid compared with conventional antibody-mediated activation owing to lack of T-cell receptor costimulation. CD3-LVs delivered genes not only selectively into T cells but also under nonactivating conditions, clearly outperforming the benchmark vector vesicular stomatitis-LV glycoproteins under these conditions. Remarkably, CD3-LVs were properly active in gene delivery even when added to whole human blood in absence of any further stimuli. Upon administration of CD3-LV into NSG mice transplanted with human peripheral blood mononuclear cells, efficient and exclusive transduction of CD3+ T cells in all analyzed organs was achieved. Finally, the most promising CD3-LV successfully delivered a CD19-specific chimeric antigen receptor (CAR) into T lymphocytes in vivo in humanized NSG mice. Generation of CAR T cells was accompanied by elimination of human CD19+ cells from blood. Taken together, the data strongly support implementation of T-cell-activating properties within T-cell-targeted vector particles. These particles may be ideally suited for T-cell-specific in vivo gene delivery.

Project description: Not available

Project description:Recent commercialization of lentiviral vector (LV)-based cell therapies and successful reports of clinical studies have demonstrated the untapped potential of LVs to treat diseases and benefit patients. LVs hold notable and inherent advantages over other gene transfer agents based on their ability to transduce non-dividing cells, permanently transform target cell genome, and allow stable, long-term transgene expression. LV systems based on non-human lentiviruses are attractive alternatives to conventional HIV-1-based LVs due to their lack of pathogenicity in humans. This article reviews non-human lentiviruses and highlights their unique characteristics regarding virology and molecular biology. The LV systems developed based on these lentiviruses, as well as their successes and shortcomings, are also discussed. As the field of gene therapy is advancing rapidly, the use of LVs uncovers further challenges and possibilities. Advances in virology and an improved understanding of lentiviral biology will aid in the creation of recombinant viral vector variants suitable for translational applications from a variety of lentiviruses.

Project description:Lentiviral vectors are the most frequently used tool to stably transfer and express genes in the context of gene therapy for monogenic diseases. The vast majority of clinical applications involves an ex vivo modality whereby lentiviral vectors are used to transduce autologous somatic cells, obtained from patients and re-delivered to patients after transduction. Examples are hematopoietic stem cells used in gene therapy for hematological or neurometabolic diseases or T cells for immunotherapy of cancer. We review the design and use of lentiviral vectors in gene therapy of monogenic diseases, with a focus on controlling gene expression by transcriptional or post-transcriptional mechanisms in the context of vectors that have already entered a clinical development phase.

Project description:Lentiviral vectors (LVs) are highly attractive as a gene therapy agent as they are able to stably integrate their genomes in both dividing and nondividing cells and, in principle, provide long-term therapeutic benefit. However, their performance in skeletal muscle in adult animals has, to date, been disappointing. In order to gain clearer insight into their utility in this tissue type, we have conducted an extensive quantitative comparison of constitutive and muscle-specific promoter activities in skeletal muscle and nonmuscle systems following LV delivery in cell lines and neonatal mice. Our data show that LV delivery to hind leg skeletal muscle of neonatal mouse results in long-term transgene expression in adulthood. We find that the human desmin (DES) promoter/enhancer is the first muscle-specific control region to match the activity of the highly active constitutive human cytomegalovirus (hCMV) promoter/enhancer in skeletal muscle within a LV context both in vitro and in vivo. Furthermore, the DES promoter/enhancer provides six- to eightfold greater expression per viral copy than the muscle-specific human muscle creatine kinase (CKM) promoter/enhancer. DES also confers a more reproducible and tissue-specific transgene expression profile compared to CKM and is therefore a highly attractive regulatory element for use in muscle gene therapy vectors.

Project description:Lentiviral vectors (LV) have seen considerably increase in use as gene therapy vectors for the treatment of acquired and inherited diseases. This review presents the state of the art of the production of these vectors with particular emphasis on their large-scale production for clinical purposes. In contrast to oncoretroviral vectors, which are produced using stable producer cell lines, clinical-grade LV are in most of the cases produced by transient transfection of 293 or 293T cells grown in cell factories. However, more recent developments, also, tend to use hollow fiber reactor, suspension culture processes, and the implementation of stable producer cell lines. As is customary for the biotech industry, rather sophisticated downstream processing protocols have been established to remove any undesirable process-derived contaminant, such as plasmid or host cell DNA or host cell proteins. This review compares published large-scale production and purification processes of LV and presents their process performances. Furthermore, developments in the domain of stable cell lines and their way to the use of production vehicles of clinical material will be presented.