Targeted vectors for gene therapy of cancer and retroviral infections

Gene therapy has developed to a technology which rapidly moved from the laboratory bench to the bedside in the clinic. This implies safe, efficient and targeted gene transfer systems for suitable application to the patient. Beside the development of such gene transfer vectors of viral or nonviral origin, improvement of cell type specific and inducible gene expression is pivotal for successful gene therapy leading to targeted gene action. Numerous gene therapy approaches for treatment of cancer and retroviral infections utilize cell type specific and/or regulatable promoter and enhancer sequences for the selective expression of therapeutic genes in the desired cell populations and tissues. In this article the recent developments and the potential of expression targeting are reviewed for gene therapy approaches of cancer and retroviral infections.     

Gene therapy for Parkinson's disease

Gene therapy is a potentially powerful approach to the treatment of neurological diseases. The discovery of neurotrophic factors inhibiting neurodegenerative processes and neurotransmitter-synthesizing enzymes provides the basis for current gene therapy strategies for Parkinson's disease. Genes can be transferred by viral or nonviral vectors. Of the various possible vectors, recombinant retroviruses are the most efficient for genetic modification of cells in vitro that can thereafter be used for transplantation (ex vivo gene therapy approach). Recently, in vivo gene transfer to the brain has been developed using adenovirus vectors. One of the advantages of recombinant adenovirus is that it can transduced both quiescent and actively dividing cells, thereby allowing both direct in vivo gene transfer and ex vivo gene transfer to neural cells. Probably because the brain is partially protected from the immune system, the expression of adenoviral vectors persists for several months with little inflammation. Novel therapeutic tools, such as vectors for gene therapy have to be evaluated in terms of efficacy and safety for future clinical trials. These vectors still need to be improved to allow long-term and possibly regulatable expression of the transgene.     

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).     

可诱导慢病毒载体的优化策略及应用

以1型人免疫缺陷病毒(HIV-1)为基础构建的慢病毒载体具有可感染非分裂细胞、免疫反应小、携带的基因片段容量大和可整合进宿主基因组而长期表达等优点,因而成为最理想的基因转移载体之一。可诱导慢病毒载体介导的可诱导基因表达系统能够有效控制目的基因表达,扩大了慢病毒载体的临床应用潜能,成为很有前景的基因治疗载体。主要介绍带有四环素和其他几种诱导系统的可调控性慢病毒载体及其改进,以及可诱导慢病毒载体在RNA干扰中的应用。     

Enhancement of gene delivery to cancer cells by a retargeted adenovirus

The inefficiency of in vivo gene transfer using currently available vectors reflects a major hurdle in cancer gene therapy. Both viral and non-viral approaches that improve gene transfer efficiency have been described, but suffer from a number of limitations. Herein, a fiber-modified adenovirus, carrying the small peptide ligand on the capsid, was tested for the delivery of a transgene to cancer cells. The fiber-modified adenovirus was able to mediate the entry and expression of a beta-galactosidase into cancer cells with increased efficiency compared to the unmodified adenovirus. Particularly, the gene transfer efficiency was improved up to 5 times in OVCAR3 cells, an ovarian cancer cell line. Such transduction systems hold promise for delivering genes to transferrin receptor overexpressing cancer cells, and could be used for future cancer gene therapy.     

Comparative study of the transfection efficiency of commonly used viral vectors in rhesus monkey (Macaca mulatta) brains

Viral vector transfection systems are among the simplest of biological agents with the ability to transfer genes into the central nervous system.In brain research,a series of powerful and novel gene editing technologies are based on these systems.Although many viral vectors are used in rodents,their full application has been limited in non-human primates.To identify viral vectors that can stably and effectively express exogenous genes within nonhuman primates,eleven commonly used recombinant adeno-associated viral and lentiviral vectors,each carrying a gene to express green or red fluorescence,were injected into the parietal cortex of four rhesus monkeys.The expression of fluorescent cells was used to quantify transfection efficiency.Histological results revealed that recombinant adeno-associated viral vectors,especially the serotype 2/9 coupled with the cytomegalovirus,human synapsin Ⅰ,or Ca2+/calmodulin-dependent protein kinase Ⅱ promoters,and lentiviral vector coupled with the human ubiquitin C promoter,induced higher expression of fluorescent cells,representing high transfection efficiency.This is the first comparison of transfection efficiencies of different viral vectors carrying different promoters and serotypes in non-human primates (NHPs).These results can be used as an aid to select optimal vectors to transfer exogenous genes into the central nervous system of non-human primates.     

Transient expression assays in grapevine: a step towards genetic improvement

In the past few years, the usefulness of transient expression assays has continuously increased for the characterization of unknown gene function and metabolic pathways. In grapevine (Vitis vinifera L.), one of the most economically important fruit crops in the world, recent systematic sequencing projects produced many gene data sets that require detailed analysis. Due to their rapid nature, transient expression assays are well suited for large‐scale genetic studies. Although genes and metabolic pathways of any species can be analysed by transient expression in model plants, a need for homologous systems has emerged to avoid the misinterpretation of results due to a foreign genetic background. Over the last 10 years, various protocols have thus been developed to apply this powerful technology to grapevine. Using cell suspension cultures, somatic embryos, leaves or whole plantlets, transient expression assays enabled the study of the function, regulation and subcellular localization of genes involved in specific metabolic pathways such as the biosynthesis of phenylpropanoids. Disease resistance genes that could be used for marker‐assisted selection in conventional breeding or for stable transformation of elite cultivars have also been characterized. Additionally, transient expression assays have proved useful for shaping new tools for grapevine genetic improvement: synthetic promoters, silencing constructs, minimal linear cassettes or viral vectors. This review provides an update on the different tools (DNA constructs, reporter genes, vectors) and methods (Agrobacterium‐mediated and direct gene transfer methods) available for transient gene expression in grapevine. The most representative results published thus far are then described.     

Recombinant polymer-protein fusion: a promising approach towards efficient and targeted gene delivery

BACKGROUND: Synthetic vectors such as polymers have the potential to reduce the safety problems associated with viral vectors; however, their low transfection efficiency limits their clinical utility. To study the critical steps involved in an efficient transgene expression, there is a need for creative approaches that allow a systematic correlation between gene carrier structure and properties necessary for successful gene transfer. Using recombinant techniques a prototype vector comprised of tandem repeating units fused to a targeting moiety was biosynthesized to mediate gene transfer in mammalian cell lines. The carrier was designed to have the structure of (KHKHKHKHKK)6-FGF2 where lysine (K) residues would allow complexation with plasmid DNA, basic fibroblast growth factor (FGF2) to target cells over-expressing FGF2 receptors (FGFR), and histidine (H) residues to facilitate escape from the endosomal compartments. METHODS: The gene carrier was biosynthesized in E. coli, purified using a Ni-NTA column, characterized, complexed with pDNA, and the complexes were used to transfect NIH 3T3, T-47D and COS-1 mammalian cell types known to express FGFR. RESULTS: Results demonstrate the successful cloning and expression of the gene carrier with over 95% purity. The molecular weight of the gene carrier was determined by MALDI-TOF to be 27 402. Amino acid content analysis and Western blot confirmed the expression of the gene carrier in E. coli. The vector was able to condense pDNA, induce cell proliferation in NIH 3T3 fibroblasts, and mediate transgene expression in NIH 3T3, T-47D and COS-1 mammalian cell types. CONCLUSION: Genetic engineering techniques show promise for systematic investigation of structure-activity relationships of non-viral gene delivery vectors.     

Development of hybrid viral vectors for gene therapy

Adenoviral, retroviral/lentiviral, adeno-associated viral, and herpesviral vectors are the major viral vectors used in gene therapy. Compared with non-viral methods, viruses are highly-evolved, natural delivery agents for genetic materials. Despite their remarkable transduction efficiency, both clinical trials and laboratory experiments have suggested that viral vectors have inherent shortcomings for gene therapy, including limited loading capacity, immunogenicity, genotoxicity, and failure to support long-term adequate transgenic expression. One of the key issues in viral gene therapy is the state of the delivered genetic material in transduced cells. To address genotoxicity and improve the therapeutic transgene expression profile, construction of hybrid vectors have recently been developed. By adding new abilities or replacing certain undesirable elements, novel hybrid viral vectors are expected to outperform their conventional counterparts with improved safety and enhanced therapeutic efficacy. This review provides a comprehensive summary of current achievements in hybrid viral vector development and their impact on the field of gene therapy.     

Novel AAV serotypes for improved ocular gene transfer

Some of the most successful gene therapy results have been obtained using recombinant viral vectors to treat animal models of inherited and acquired ocular diseases. Clinical trials using adenovirus vector systems have been initiated for two ocular diseases. Adeno-associated viruses (AAVs) represent an attractive alternative to adenoviral vector systems as they enable stable and long-term expression and can target a variety of different ocular cell types depending on the capsid serotype; recently clinical trails for congenital blindness was initiated with a vector-based AAV serotype 2. High levels of retinal gene transfer have been achieved using vectors based on AAV serotypes 1, 2, 4 and 5. This report compares the gene transfer efficacy and stability of expression of vector systems based on three novel AAV serotypes: AAV7, 8, 9, with the established vectors AAV1, 2, 5. We show here that AAV7 and 8 enable superior long-term transduction of retinal and also anterior chamber structures.     

Techniques in plant molecular biology--progress and problems

Progress in plant molecular biology has been dependent on efficient methods of introducing foreign DNA into plant cells. Gene transfer into plant cells can be achieved by either direct uptake of DNA or the natural process of gene transfer carried out by the soil bacterium Agrobacterium. Versatile gene-transfer vectors have been developed for use with Agrobacterium and more recently vectors based on the genomes of plant viruses have become available. Using this technology the expression of foreign DNA, the functional analysis of plant DNA sequences, the investigation of the mechanism of viral DNA replication and cell to cell spread, as well as the study of transposition, can be carried out. In addition, the versatility of the gene-transfer vectors is such that they may be used to isolate genes not amenable to isolation using conventional protocols. This review concentrates on these aspects of plant molecular biology and discusses the limitations of the experimental systems that are currently available.     

Adeno-associated viral vectors for gene transfer and gene therapy.

Adeno-associated virus (AAV) is a defective, non-pathogenic human parvovirus that depends for growth on coinfection with a helper adenovirus or herpes virus. Recombinant adeno-associated viruses (rAAVs) have attracted considerable interest as vectors for gene therapy. In contrast to other gene delivery systems, rAAVs lack all viral genes and show long-term gene expression in vivo without immune response or toxicity. Over the past few years, many applications of rAAVs as therapeutic agents have demonstrated the utility of this vector system for long-lasting genetic modification and gene therapy in preclinical models of human disease. New production methods have increased rAAV vector titers and eliminated contamination by adenovirus. In addition, vectors for regulatable gene expression and vectors retargeted to different cells have been engineered. These advancements are expected to accelerate and facilitate further animal model studies, providing validation for use of rAAVs in human clinical trials.     

The evolution of heart gene delivery vectors

Gene therapy holds promise for treating numerous heart diseases. A key premise for the success of cardiac gene therapy is the development of powerful gene transfer vehicles that can achieve highly efficient and persistent gene transfer specifically in the heart. Other features of an ideal vector include negligible toxicity, minimal immunogenicity and easy manufacturing. Rapid progress in the fields of molecular biology and virology has offered great opportunities to engineer various genetic materials for heart gene delivery. Several nonviral vectors (e.g. naked plasmids, plasmid lipid/polymer complexes and oligonucleotides) have been tested. Commonly used viral vectors include lentivirus, adenovirus and adeno-associated virus. Among these, adeno-associated virus has shown many attractive features for pre-clinical experimentation in animal models of heart diseases. We review the history and evolution of these vectors for heart gene transfer.     

pLR: A lentiviral backbone series to stable transduction of bicistronic genes and exchange of promoters

Gene transfer based on lentiviral vectors allow the integration of exogenous genes into the genome of a target cell, turning these vectors into one of the most used methods for stable transgene expression in mammalian cells, in vitro and in vivo. Currently, there are no lentivectors that allow the cloning of different genes to be regulated by different promoters. Also, there are none that permit the analysis of the expression through an IRES (internal ribosome entry site) - reporter gene system. In this work, we have generated a series of lentivectors containing: (1) a malleable structure to allow the cloning of different target genes in a multicloning site (mcs); (2) unique site to exchange promoters, and (3) IRES followed by one of two reporter genes: eGFP or DsRed. The series of the produced vectors were named pLR (for lentivirus and RSV promoter) and were fairly efficient with a strong fluorescence of the reporter genes in direct transfection and viral transduction experiments. This being said, the pLR series have been found to be powerful biotechnological tools for stable gene transfer and expression.     

Genetic modification of baculovirus expression vectors

As a protein expression vector,the baculovirus demonstrates many advantages over other vectors.With the development of biotechnology,baculoviral vectors have been genetically modified to facilitate hig...