Cell cycle independent infection and gene transfer by recombinant Sendai viruses

A common problem for viral vectors in the field of somatic gene therapy is the dependence of an efficient cellular transduction on the cell cycle phase of target cells. An optimized viral vector system should therefore transduce cells in different cell cycle phases equally to improve transduction efficiencies. Recent observations that recombinant Sendai viruses (SeV) can infect a broad range of different tissues suggested SeV to be a good candidate for future gene therapeutic strategies in which dividing and non-dividing cells have to be reached. However, detailed data on the influence of distinct cell cycle phases on the infection of SeV or related viruses are missing. We report that synchronization of NIH 3T3 cells as well as contact inhibition of human fibroblast cells did not exhibit any negative influence on SeV infection rates. Furthermore, different attractive target tissues like human umbilical cord derived cells or primary human hepatocytes can be reached by SeV efficiently. As an important information for further cell cycle studies of paramyxoviruses we discovered surprisingly that the DNA polymerase inhibitor aphidicolin (induces a G(1)/M arrest) functions as an inhibitor of SeV but not of an adenoviral expression vector. In conclusion, the results demonstrate SeV based vector particles to be an ideal tool to reach equally cells coexisting in different cell cycle phases.     

Comparison between Sendai virus and adenovirus vectors to transduce HIV-1 genes into human dendritic cells

Immuno-genetherapy using dendritic cells (DCs) can be applied to human immunodeficiency virus type 1 (HIV-1) infection. Sendai virus (SeV) has unique features such as cytoplasmic replication and high protein expression as a vector for genetic manipulation. In this study, we compared the efficiency of inducing green fluorescent protein (GFP) and HIV-1 gene expression in human monocyte-derived DCs between SeV and adenovirus (AdV). Human monocyte-derived DCs infected with SeV showed the maximum gene expression 24 hr after infection at a multiplicity of infection (MOI) of 2. Although SeV vector showed higher cytopathic effect on DCs than AdV, SeV vector induced maximum gene expression earlier and at much lower MOI. In terms of cell surface phenotype, both SeV and AdV vectors induced DC maturation. DCs infected with SeV as well as AdV elicited HIV-1 specific T-cell responses detected by interferon gamma (IFN-gamma) enzyme-linked immunospot (Elispot). Our data suggest that SeV could be one of the reliable vectors for immuno-genetherapy for HIV-1 infected patients.     

Delivery of Viral Vectors to Tumor Cells: Extracellular Transport, Systemic Distribution, and Strategies for Improvement

It is a challenge to deliver therapeutic genes to tumor cells using viral vectors because (i) the size of these vectors are close to or larger than the space between fibers in extracellular matrix and (ii) viral proteins are potentially toxic in normal tissues. In general, gene delivery is hindered by various physiological barriers to virus transport from the site of injection to the nucleus of tumor cells and is limited by normal tissue tolerance of toxicity determined by local concentrations of transgene products and viral proteins. To illustrate the obstacles encountered in the delivery and yet limit the scope of discussion, this review focuses only on extracellular transport in solid tumors and distribution of viral vectors in normal organs after they are injected intravenously or intratumorally. This review also discusses current strategies for improving intratumoral transport and specificity of viral vectors.     

Light directed gene transfer by photochemical internalisation

Numerous gene therapy vectors, both viral and non-viral, are taken into the cell by endocytosis, and for efficient gene delivery the therapeutic genes carried by such vectors have to escape from endocytic vesicles so that the genes can further be translocated to the nucleus. Since endosomal escape is often an inefficient process, release of the transgene from endosomes represents one of the most important barriers for gene transfer by many such vectors. To improve endosomal escape we have developed a new technology, named photochemical internalisation (PCI). In this technology photochemical reactions are initiated by photosensitising compounds localised in endocytic vesicles, inducing rupture of these vesicles upon light exposure. The technology constitutes an efficient light-inducible gene transfer method in vitro, where light-induced increases in transfection or viral transduction of more than 100 and 30 times can be observed, respectively. The method can potentially be developed into a site-specific method for gene delivery in vivo. This article will review the background for the PCI technology, and several aspects of PCI induced gene delivery with synthetic and viral vectors will be discussed. Among these are: (i) The efficiency of the technology with different gene therapy vectors; (ii) use of PCI with targeted vectors; (iii) the timing of DNA delivery relative to the photochemical treatment. The prospects of using the technology for site-specific gene delivery in vivo will be thoroughly discussed, with special emphasis on the possibilities for clinical use. In this context our in vivo experience with the PCI technology as well as the clinical experience with photodynamic therapy will be treated, as this is highly relevant for the clinical use of PCI-mediated gene delivery. The use of photochemical treatments as a tool for understanding the more general mechanisms of transfection will also be discussed.     

Friendly fire: redirecting herpes simplex virus-1 for therapeutic applications

Herpes simplex virus-1 (HSV-1) is a relatively large double-stranded DNA virus encoding at least 89 proteins with well characterized disease pathology. An understanding of the functions of viral proteins together with the ability to genetically engineer specific viral mutants has led to the development of attenuated HSV-1 for gene therapy. This review highlights the progress in creating attenuated genetically engineered HSV-1 mutants that are either replication competent (viral non-essential gene deleted) or replication defective (viral essential gene deleted). The choice between a replication-competent or -defective virus is based on the end-goal of the therapeutic intervention. Replication-competent HSV-1 mutants have primarily been employed as antitumor oncolytic viruses, with the lytic nature of the virus harnessed to destroy tumor cells selectively. In replacement gene therapy, replication-defective viruses have been utilized as delivery vectors. The advantages of HSV-1 vectors are that they infect quiescent and dividing cells efficiently and can encode for relatively large transgenes.     

Viral mediated gene transfer to sprouting blood vessels during angiogenesis

Several experimental systems have been applied to investigate the development of new blood vessels. Angiogenesis can be followed ex-vivo by culturing explants of rat aorta 'rings' in biomatrix gels. This angiogenesis system was modified for the study of viral vector mediated gene transfer, using adenovirus, vaccinia- and retroviral vectors. Two modifications were introduced to the model in order to facilitate efficient viral mediated gene transfer, (i) placing the aorta ring on top of a thin layer of collagen such that the angiogenic tissue will be accessible to the viral vector; and (ii) infection of the aorta rings prior to embedding them into the collagen matrix. While adenovirus and vaccinia vectors infected efficiently the aorta rings they induced cell death. Subsequent gene transfer experiments were, therefore, carried with retroviral vectors containing vascular endothelial growth factor (VEGF) and the beta-interferon (IFN) genes. Overexpression of VEGF enhanced significantly microvessel sprouting, while overexpression of IFN-beta induced an antiviral effect. The experimental system described in this study can facilitate the application of other viral vectors to the study of genes that may regulate the complex angiogenic process and thereby open new avenues for vascular gene therapy.     

Characterization of the lymphotropic amplicons-6 and tamplicon-7 vectors derived from HHV-6 and HHV-7

Amplicon-6 and Tamplicon-7 are novel non-integrating vectors derived from the lymphotropic Human Herpesviruses 6 and 7 (HHV-6 and HHV-7). In the presence of helper viruses the amplicon vectors replicate to yield packaged defective genomes of size approximately 150 kb and consisting of multiple repeat units containing (i) the oriLyt DNA replication origin (ii) the pac-1 and pac-2 cleavage and packaging signals (iii) bacterial plasmid DNA sequences (iv) the chosen transgene(s). Employing CD46 as a receptor HHV-6 gains entry into varied cells, including lymphocytes and dendritic cells, whereas HHV-7 employs the CD4 receptor to target CD4+ cells. The amplicon-based vectors have facilitated the characterization of viral DNA replication and packaging. Following electroporation and helper virus superinfection, the vectors can be transmitted as cell associated and as cell-free virions secreted into the medium. Analyses by flow cytometry have shown good cell spread and efficient gene expression. Exemplary transgenes have included: (i) The Green Fluorescence Protein (GFP) (ii) Genes for potential use in anti-viral vaccination e.g., the HSV-1 glycoprotein D (gD) with and without the trans-membrane region, expressed intracellularly, at the cell membrane or as secreted proteins. (iii) Tumor cell antigens. (iv) Apoptotic genes for development of oncolytic vectors. Due to their cell tropism, their structure as concatemeric genomes, with less than 1.5 kb of viral DNA sequences, the HHV-6 and 7 amplicons have the potential to become unique vectors for immunization and lymphotropic gene therapy.     

The history of the HSV amplicon: from naturally occurring defective genomes to engineered amplicon vectors

We have derived the HSV amplicon vector in 1981/1982 after elaborate experience with "defective viruses", arising spontaneously in viral stocks propagated at high multiplicities of infection (m.o.i.). The defective viruses were found to contain large concatemeric genomes with repeat units of limited complexity. We employed cloned defective genome repeats to generate the "amplicon" vectors, which in the presence of helper virus replicate to produce packaged large concatemeric genomes, transmissible to uninfected cells. The cloned amplicons were then employed to fine map and analyze the signals essential for amplicon propagation: (i) A DNA replication origin, producing concatemeric genomes by rolling circle replication. Three DNA replication origins were identified in the HSV genome. (ii) Signals termed pac-1 and pac-2, directing a measuring function for coordinate cleavage of the concatemeric genomes and their packaging as full-size (150 kb) genomes. Using amplicons, foreign genes of large sizes could be linked to less than 1 kb of the cis-acting HSV DNA sequences and become amplified in packaged defective genomes, transmissible to new cells. The transgenes are expressed efficiently, due to sequence reiterations. Large quantities of vectors can be produced in vitro. The amplicons are attractive vectors for use as non-integrating gene delivery vectors. The packaging signals pac-1 and pac-2 are well conserved in different herpesviruses and amplicons with a DNA replication origin and cleavage and packaging signals have been produced in additional herpesviruses. Depending on amplicon-host cell combination, the vectors can be employed with and without mutated helper virus(es) to obtain high gene expression, and desired effect on the target cell. In the absence of helper virus, the defective virus produced is limited for spread in the targeted cells. We expect that new vectors employing state of the art transgenes, will be developed to generate amplicon based concatemeric defective viruses capable of efficient expression of these genes.     

Core labeling of adenovirus with EGFP

The study of adenovirus could greatly benefit from diverse methods of virus detection. Recently, it has been demonstrated that carboxy-terminal EGFP fusions of adenovirus core proteins Mu, V, and VII properly localize to the nucleus and display novel function in the cell. Based on these observations, we hypothesized that the core proteins may serve as targets for labeling the adenovirus core with fluorescent proteins. To this end, we constructed various chimeric expression vectors with fusion core genes (Mu-EGFP, V-EGFP, preVII-EGFP, and matVII-EGFP) while maintaining expression of the native proteins. Expression of the fusion core proteins was suboptimal using E1 expression vectors with both conventional CMV and modified (with adenovirus tripartite leader sequence) CMV5 promoters, resulting in non-labeled viral particles. However, robust expression equivalent to the native protein was observed when the fusion genes were placed in the deleted E3 region. The efficient Ad-wt-E3-V-EGFP and Ad-wt-E3-preVII-EGFP expression vectors were labeled allowing visualization of purified virus and tracking of the viral core during early infection. The vectors maintained their viral function, including viral DNA replication, viral DNA encapsidation, cytopathic effect, and thermostability. Core labeling offers a means to track the adenovirus core in vector targeting studies as well as basic adenovirus virology.     

Approaches to utilize mesenchymal progenitor cells as cellular vehicles

Mammalian cells represent a novel vector approach for gene delivery that overcomes major drawbacks of viral and nonviral vectors and couples cell therapy with gene delivery. A variety of cell types have been tested in this regard, confirming that the ideal cellular vector system for ex vivo gene therapy has to comply with stringent criteria and is yet to be found. Several properties of mesenchymal progenitor cells (MPCs), such as easy access and simple isolation and propagation procedures, make these cells attractive candidates as cellular vehicles. In the current work, we evaluated the potential utility of MPCs as cellular vectors with the intent to use them in the cancer therapy context. When conventional adenoviral (Ad) vectors were used for MPC transduction, the highest transduction efficiency of MPCs was 40%. We demonstrated that Ad primary-binding receptors were poorly expressed on MPCs, while the secondary Ad receptors and integrins presented in sufficient amounts. By employing Ad vectors with incorporated integrin-binding motifs (Ad5lucRGD), MPC transduction was augmented tenfold, achieving efficient genetic loading of MPCs with reporter and anticancer genes. MPCs expressing thymidine kinase were able to exert a bystander killing effect on the cancer cell line SKOV3ip1 in vitro. In addition, we found that MPCs were able to support Ad replication, and thus can be used as cell vectors to deliver oncolytic viruses. Our results show that MPCs can foster expression of suicide genes or support replication of adenoviruses as potential anticancer therapeutic payloads. These findings are consistent with the concept that MPCs possess key properties that ensure their employment as cellular vehicles and can be used to deliver either therapeutic genes or viruses to tumor sites.     

Towards construction of viral vectors based on avian coronavirus infectious bronchitis virus for gene delivery and vaccine development

Manipulation of the coronavirus genome to accommodate and express foreign genes is an attractive approach for gene delivery and vaccine development. By using an infectious cloning system developed recently for the avian coronavirus infectious bronchitis virus (IBV), the enhanced green fluorescent protein (EGFP) gene, the firefly luciferase gene and several host and viral genes (eIF3f, SARS ORF6, Dengue virus 1 core protein gene) were inserted into various positions of the IBV genome, and the effects on gene expression, virus recovery, and stability in cell culture were studied. Selected viruses were also inoculated into chicken embryos for studies of foreign gene expression at different tissue level. The results demonstrated the stability of recombinant viruses depends on the intrinsic properties of the foreign gene itself as well as the position at which the foreign genes were inserted. For unstable viruses, the loss of expression of the inserted genes was found to result from a large deletion of the inserted gene and even IBV backbone sequences. This represents a promising system for development of coronavirus-based gene delivery vectors and vaccines against coronavirus and other viral infections in chicken.     

HSV-1-derived recombinant and amplicon vectors for gene transfer and gene therapy

Herpes simplex virus type 1 (HSV-1) is a major human pathogen whose lifestyle is based on a long-term dual interaction with the infected host characterized by the existence of lytic and latent infections. Although in most cell types infection with HSV-1 will induce toxic effects ending in the death of the infected cells, the very deep knowledge we possess on the genetics and molecular biology of HSV-1 has permitted the deletion of most toxic genes and the development of non-pathogenic HSV-1-based vectors for gene transfer. Several unique features of HSV-1 make vectors derived from this virus very appealing for preventive or therapeutic gene transfer. These include (i) the very high transgenic capacity of the virus particle, authorizing to convey very large pieces of foreign DNA to the nucleus of mammalian cells, (ii) the genetic complexity of the virus genome, allowing to generate many different types of attenuated vectors possessing oncolytic activity, and (iii) the ability of HSV-1 vectors to invade and establish lifelong non-toxic latent infections in neurons from sensory ganglia and probably in other neurons as well, from where transgenes can be strongly and long-term expressed. Three different classes of vectors can be derived from HSV-1: replication-competent attenuated vectors, replication-incompetent recombinant vectors, and defective helper-dependent vectors known as amplicons. Each of these different vectors attempts to exploit one or more of the above-mentioned features of HSV-1. In this review we will update the current know-how concerning design, construction, and recent applications, as well as the potential and current limitations of the three different classes of HSV-1-based vectors.     

Molecular cloning, expression, and antigenicity of Seto virus belonging to genogroup I Norwalk-like viruses

The viral capsid protein of the Seto virus (SeV), a Japanese strain of genogroup I Norwalk-like viruses (NLVs), was expressed as virus-like particles using a baculovirus expression system. An antigen detection enzyme-linked immunosorbent assay based on hyperimmune antisera to recombinant SeV was highly specific to homologous SeV-like strains but not heterologous strains in stools, allowing us type-specific detection of NLVs.     

Why do we need new gene therapy viral vectors? Characteristics, limitations and future perspectives of viral vector transduction

The use of viruses to transduce genes of interest into mammalian cells has been extremely revolutionary, both in terms of laboratory research and for clinical purposes. This approach has allowed expression and over-expression of proteins of interest as well as the understanding of both virus life cycles and eukaryotic cell mechanisms. Beginning in the late eighties gene transduction has been applied to clinical trials but mainly restricted to cancer treatment and genetic diseases. More recently it has been proposed for the cure of infectious diseases (AIDS), vascular diseases and others (Alzheimer's and Parkinson's disease). Viral vectors have been progressively modified in order to increase their transduction efficiency and to reduce their toxicity, immunogenicity and inflammatory potential. In this respect, much has been done in the last few years. By adding genes belonging to other viral species to the vectors' DNA, scientists were able to re-direct their tissue-specificity or to control protein expression. More recently, in the attempt of overcoming the limitations of each viral species, so-called chimeric viral vectors have been generated by combining favourable features of two or more different viruses into one. This review summarises the main characteristics of the most common viral vectors, including their advantages, limitations and possible future applications. It also briefly discusses development and evolution of chimeric vectors, treated in more details along this entire issue. Finally, we evaluate basic safety aspects, mandatory to consider for the clinical application of viral gene transduction.