Lentiviral vectors

The delivery of genetic material to mammalian cells is of great importance for modern fundamental biology, biomedicine, biotechnology, agriculture, and veterinary medicine. The development of new efficient techniques of gene transfer to human cells led to the advent of gene therapy, a novel approach to treating severe metabolic disorders, some viral infections (including HIV infection), autoimmune diseases, and genetic defects causing cancer. The review considers the main principles of constructing gene transfer and expression systems based on lentiviruses, a powerful tool for human gene therapy and transgenic research, with a special focus on the genome structure and life cycle of lentiviruses and the design and safety of lentiviral vector systems.     

Lentiviral vectors

Vectors based on lentiviruses have reached a state of development such that clinical studies using these agents as gene delivery vehicles have now begun. They have particular advantages for certain in vitro and in vivo applications especially the unique capability of integrating genetic material into the genome of non-dividing cells. Their rapid progress into clinical use reflects in part the huge body of knowledge which has accumulated about HIV in the last 20 years. Despite this, many aspects of viral assembly on which the success of these vectors depends are rather poorly understood. Sufficient is known however to be able to produce a safe and reproducible high titre vector preparation for effective transduction of growth-arrested tissues such as neural tissue, muscle and liver.     

Lentiviral vectors

The delivery of genetic material to mammalian cells has a great importance for modern fundamental biology, biomedicine, biotechnology, agriculture and veterinary medicine. The development of new efficient techniques of gene transfer to human cells has led to the establishment of gene therapy, a novel type of treatment targeting severe metabolic disorders, some viral infections, including HIV, autoimmune diseases and genetic defects causing cancer. This review summarizes the achievements in lentiviral-mediated gene transfer, a powerful tool for use in human gene therapy and transgenic research, with a special focus on the genome structure and life cycle of lentiviruses, as well as on the design and safety aspects of lentiviral vector systems.     

Zebrafish kidney development: basic science to translational research

The zebrafish has become a significant model system for studying renal organogenesis and disease, as well as for the quest for new therapeutics, because of the structural and functional simplicity of the embryonic kidney. Inroads to the nature and disease states of kidney-related ciliopathies and acute kidney injury (AKI) have been advanced by zebrafish studies. This model organism has been instrumental in the analysis of mutant gene function for human disease with respect to ciliopathies. Additionally, in the AKI field, recent work in the zebrafish has identified a bona fide adult zebrafish renal progenitor (stem) cell that is required for neo-nephrogenesis, both during the normal lifespan and in response to renal injury. Taken together, these studies solidify the zebrafish as a successful model system for studying the broad spectrum of ciliopathies and AKI that affect millions of humans worldwide, and point to a very promising future of zebrafish drug discovery. The emphasis of this review will be on the role of the zebrafish as a model for human kidney-related ciliopathies and AKI, and how our understanding of these complex pathologies is being furthered by this tiny teleost.     

Lentiviral vectors for gene delivery into cells

Human immunodeficiency virus type I (HIV) is the etiologic agent of acquired immunodeficiency syndrome or AIDS. Vectors based upon HIV have been in use for over a decade. Beginning in 1996, with the demonstration of improved pseudotyping using vesicular stomatitis virus (VSV) G protein along with transduction of resting mammalian cells, a series of improvements have been made in these vectors, making them both safer and more efficacious. Taking a cue from vector development of murine leukemia virus (MLV), split coding and self-inactivating HIV vectors now appear quite suitable for phase I clinical trials. In parallel, a number of pre-clinical efficacy studies in animals have demonstrated the utility of these vectors for various diseases processes, especially neurodegenerative and hematopoietic illnesses. These vectors are also appropriate for the study of other viruses (specifically of viral entry) and investigation of the HIV replicative cycle, along with straightforward transgene delivery to target cells of interest. Vectors based upon other lentiviruses have shown similar abilities and promise. Although concerns remain, particularly with regards to detection and propagation of replication-competent lentivirus, it is almost certain that these vectors will be introduced into the clinic within the next 3-5 years.     

Lentiviral vectors that carry anti-HIV shRNAs: problems and solutions

BACKGROUND: HIV-1 replication can be inhibited with RNA interference (RNAi) by expression of short hairpin RNA (shRNA) from a lentiviral vector. Because lentiviral vectors are based on HIV-1, viral sequences in the vector system are potential targets for the antiviral shRNAs. Here, we investigated all possible routes by which shRNAs can target the lentiviral vector system. METHODS: Expression cassettes for validated shRNAs with targets within HIV-1 Leader, Gag-Pol, Tat/Rev and Nef sequences were inserted in the lentiviral vector genome. Third-generation self-inactivating HIV-1-based lentiviral vectors were produced and lentiviral vector capsid production and transduction titer determined. RESULTS: RNAi against HIV-1 sequences within the vector backbone results in a reduced transduction titer while capsid production was unaffected. The notable exception is self-targeting of the shRNA encoding sequence, which does not affect transduction titer. This is due to folding of the stable shRNA hairpin structure, which masks the target for the RNAi machinery. Targeting of Gag-Pol mRNA reduces both capsid production and transduction titer, which was improved with a human codon-optimized Gag-Pol construct. When Rev mRNA was targeted, no reduction in capsid production and transduction titer was observed. CONCLUSIONS: Lentiviral vector titers can be negatively affected when shRNAs against the vector backbone and the Gag-Pol mRNA are expressed during lentiviral vector production. Titer reductions due to targeting of the Gag-Pol mRNA can be avoided with a human codon-optimized Gag-Pol packaging plasmid. The remaining targets in the vector backbone may be modified by point mutations to resist RNAi-mediated degradation during vector production.     

Immunobiology of pregnancy: from basic science to translational medicine

Embryo implantation failure and spontaneous abortions represent the main causes of infertility in developed countries. Unfortunately, incomplete knowledge of the multiple factors involved in implantation and fetal development keeps the success rate of medically assisted procreation techniques relatively low. According to recent literature, cellular and molecular mechanisms of ‘immunogenic tolerance’ towards the embryo are crucial to establish an ‘anti-inflammatory’ state permissive of a healthy pregnancy. In this review we dissect the role played by the immune system in the endometrial–embryo crosstalk, with a particular emphasis towards the fork-head-box-p3 (Foxp3⁺) CD4⁺CD25⁺ regulatory T (Treg) cells and discuss the most recent therapeutic advances in the context of early immune-mediated pregnancy loss.     

Lentiviral vectors: optimization of packaging, transduction and gene expression

Gene transfer vectors based on retroviruses including oncogenic retroviruses and lentiviruses provide effective means for the delivery, integration and expression of exogenous genes in mammalian cells. Lentiviral (LV) vectors provide attractive gene delivery vehicles in the context of non-dividing cells. This review summarizes the different optimized LV genetic systems that have been developed to date. In all cases, the production of LV-derived vectors consists of a genetically split gene expression design. The viral elements that are specifically required are (i). the LV packaging helper proteins consisting of at least the gag-pol genes, (ii). the LV transfer vector RNA containing the transgene expression cassette, and (iii). an heterologous glycoprotein. While the genetic requirements and performances of the two former viral elements will be treated herein, the latter element relative to the envelope pseudotyping of LV vectors will not be further described (cf. review by Cosset in this issue).     

Lentiviral vectors for treating and modeling human CNS disorders

Vectors based on lentiviruses efficiently deliver genes into many different types of primary neurons from a broad range of species including man and the resulting gene expression is long term. These vectors are opening up new approaches for the treatment of neurological diseases such as Parkinson's disease (PD), Huntington's disease (HD), and motor neuron diseases (MNDs). Numerous animal studies have now been undertaken with these vectors and correction of disease models has been obtained. Lentiviral vectors also provide a new strategy for in vivo modeling of human diseases; for example, the lentiviral-mediated overexpression of mutated human alpha-synuclein or huntingtin genes in basal ganglia induces neuronal pathology in animals resembling PD and HD in man. These vectors have been refined to a very high level and can be produced safely for the clinic. This review will describe the general features of lentiviral vectors with particular emphasis on vectors derived from the non-primate lentivirus, equine infectious anemia virus (EIAV). It will then describe some key examples of genetic correction and generation of genetic animal models of neurological diseases. The prospects for clinical application of lentiviral vectors for the treatment of PD and MNDs will also be outlined.     

The application of basic science to translational cancer research

A report on the inaugural symposium of the Hutchison/MRC Research Centre, Cambridge, UK, 24-25 October 2002.     

Lentiviral vector-mediated gene transfer to endotherial cells compared with adenoviral and retroviral vectors

Human immunodeficiency virus (HIV, lentivirus) vector has attractive features for gene therapy, including the ability to transduce non-dividing cells and long-term transgene expression. We have already reported that lentivirus vector can transduce well-differentiated rat cardiac myocytes. Endothelial cells (EC) are an attractive target for gene therapy, both for the treatment of cardiovascular disease and for the systemic delivery of recombinant gene products directly into the circulation. There are several reports regarding application of adenovirus and retrovirus based vectors to EC. However, there have been few reports which show the effect to lentivirus-mediated gene transfer efficiency, compared with adenovirus and retrovirus. In this study, bovine aortic endothelial cells (BAECs) were infected, in vitro, with these virus vectors. Transduction efficiency (TE) of beta-Gal gene transfer in BAECs by adenovirus, lentivirus, or retrovirus at MOI10 (Multiplicity of infection) (determined on Hela cells) is 69+/-11, 33+/-8, or 22+/-6% respectively. In adenovirus and lentivirus, almost 100% of BAECs were transduced at MOI 50. However, in retrovirus, TE showed only 48+/-6% at MOI 50 and no increase at MOI 100. The percentage of beta-Gal positive cells was decreased rapidly at longer passage of cells after being transduced by adenovirus. However, lentivirus and retrovirus showed sustained higher percentage of positive cells. Furthermore, transduction by lentiviral vectors had no significant effect on viability of BAECs. Our results indicate that lentivirus showed high-level and long term gene expression in BAECs. Lentivirus can be an effective vector for the ex vivo, genetically modified EC implantation and in vivo gene therapy.     

CRISPR/Cas9-mediated genome editing: From basic research to translational medicine

The recent development of the CRISPR/Cas9 system as an efficient and accessible programmable genome-editing tool has revolutionized basic science research. CRISPR/Cas9 system-based technologies have armed researchers with new powerful tools to unveil the impact of genetics on disease development by enabling the creation of precise cellular and animal models of human diseases. The therapeutic potential of these technologies is tremendous, particularly in gene therapy, in which a patient-specific mutation is genetically corrected in order to treat human diseases that are untreatable with conventional therapies. However, the translation of CRISPR/Cas9 into the clinics will be challenging, since we still need to improve the efficiency, specificity and delivery of this technology. In this review, we focus on several in vitro, in vivo and ex vivo applications of the CRISPR/Cas9 system in human disease-focused research, explore the potential of this technology in translational medicine and discuss some of the major challenges for its future use in patients.     

Lentiviral vectors: excellent tools for experimental gene transfer and promising candidates for gene therapy

Lentiviral vectors are tools for gene transfer derived from lentiviruses. From their first application to now they have been strongly developed in design, in biosafety and in their ability of transgene expression into target cells. Primate and non-primate derived lentiviral vectors are now available and with both types of systems a lot of studies tuned to improve their performances in a large number of tissues are ongoing. Here we review the state of the art of lentiviral vector systems discussing their potential for gene therapy.     

Lentiviral vectors pseudotyped with envelope glycoproteins derived from human parainfluenza virus type 3

We describe the generation of lentiviruses pseudotyped with human parainfluenza type 3 envelope (HPIV3) glycoproteins. Lentivirus particles, expressed in 293T/17 cells, incorporate HPIV3 hemagglutinin-neuraminidase (HN) and fusion (F) proteins into their lipid bilayers and are able to transduce human kidney epithelial cells and polarized MDCK cells. Neuraminidase, AZT, and anti-HPIV3 antisera block transduction, which is consistent with lentiviral-mediated transduction via sialated receptors for HPIV3. Our findings show that HPIV3 pseudotyped lentiviruses can be formed and may have a number of useful properties for human gene transfer.