Efficient cDNA cloning by direct phenotypic correction of a mutant human cell line (HPRT-) using an Epstein-Barr virus-derived cDNA expression vector

Adenovirus-Mediated Gene Delivery: Potential Applications for Gene and Cell-Based Therapies in the New Era of Personalized Medicine

With rapid advances in understanding molecular pathogenesis of human diseases in the era of genome sciences and systems biology, it is anticipated that increasing numbers of therapeutic genes or targets will become available for targeted therapies. Despite numerous setbacks, efficacious gene and/or cell-based therapies still hold the great promise to revolutionize the clinical management of human diseases. It is wildly recognized that poor gene delivery is the limiting factor for most in vivo gene therapies. There has been a long-lasting interest in using viral vectors, especially adenoviral vectors, to deliver therapeutic genes for the past two decades. Among all currently available viral vectors, adenovirus is the most efficient gene delivery system in a broad range of cell and tissue types. The applications of adenoviral vectors in gene delivery have greatly increased in number and efficiency since their initial development. In fact, among over 2,000 gene therapy clinical trials approved worldwide since 1989, a significant portion of the trials have utilized adenoviral vectors. This review aims to provide a comprehensive overview on the characteristics of adenoviral vectors, including adenoviral biology, approaches to engineering adenoviral vectors, and their applications in clinical and pre-clinical studies with an emphasis in the areas of cancer treatment, vaccination and regenerative medicine. Current challenges and future directions regarding the use of adenoviral vectors are also discussed. It is expected that the continued improvements in adenoviral vectors should provide great opportunities for cell and gene therapies to live up to its enormous potential in personalized medicine.

An innovative strategy to clone positive modifier genes of defects caused by mtDNA mutations: MRPS18C as suppressor gene of m.3946G>A mutation in MT-ND1 gene

We have developed a new functional complementation approach to clone modifier genes which overexpression is able to suppress the biochemical defects caused by mtDNA mutations (suppressor genes). This strategy consists in transferring human genes into respiratory chain-deficient fibroblasts, followed by a metabolic selection in a highly selective medium. We used a normalized expression cDNA library in an episomal vector (pREP4) to transfect the fibroblasts, and a medium with glutamine and devoid of any carbohydrate source to select metabolically. Growing the patient's fibroblasts in this selective medium, the deficient cells rapidly disappear unless they are rescued by the cDNA of a suppressor gene. The use of an episomal vector allows us to carry out several rounds of transfection/selection (cyclical phenotypic rescue) to enrich the rescue with true clones of suppressor genes. Using fibroblasts from a patient with epileptic encephalopathy with the m.3946G>A (p.E214K) mutation in the MT-ND1 gene, several candidate genes were identified and one of them was characterized functionally. Thus, overexpression of MRPS18C gene (that encode for bS18m protein) suppressed the molecular defects produced by this mtDNA mutation, recovering the complex I activity and reducing the ROS produced by this complex to normal levels. We suggest that modulation of bS18m expression may be an effective therapeutic strategy for the patients with this mutation.

Chromatin-binding regions of EBNA1 protein facilitate the enhanced transfection of Epstein-Barr virus-based vectors

Epstein-Barr virus (EBV)-based vectors can stably maintain large genomic fragments in mammalian cells, offering great potential for the treatment/correction of many acquired and inherited disorders. Numerous studies report marked increases in the transfection efficiency of EBV-based vectors after delivery into cell lines constitutively expressing Epstein-Barr nuclear antigen-1 (EBNA1), compared with cells not expressing EBNA1. We employ a novel strategy, involving the transfection of mRNA encoding EBNA1, to transiently express EBNA1 protein in human cells. Subsequently we show that the transfection efficiency of a 21-kb EBVbased vector is improved significantly when codelivered with mRNA encoding EBNA1. Similar increases in transfection efficiency were observed after delivery of the plasmid into cells constitutively expressing EBNA1. We also investigate the mechanism by which EBNA1 facilitates the transfection of EBV-based vectors, using mRNA encoding modified versions of the protein. Previous studies suggest that the EBNA1 DNA-binding domain (DBD), together with the nuclear localization signal (NLS), may enhance transfection of EBV plasmids by facilitating their nuclear transport. We demonstrate that an EBNA1 derivative comprising only the NLS and DBD does not facilitate transfection of EBV-based vectors. However, cells expressing an EBNA1 derivative devoid of a functional NLS but retaining the chromatin-binding regions, domains A and B, enhances plasmid transfection efficiency by up to 10-fold. Moreover, a variant of EBNA1 comprising two copies of domain A fused to the DBD enhances DNA transfection to an even greater extent than wild-type EBNA1. We therefore propose that EBNA1-mediated transfection of EBV-based vectors is dependent on the presence of chromatin- binding regions and the DBD, but not the NLS.

Genetic modification of hematopoietic stem cells with nonviral systems: past progress and future prospects

Serious unwanted complications provoked by retroviral gene transfer into hematopoietic stem cells (HSCs) have recently raised the need for the development and assessment of alternative gene transfer vectors. Within this context, nonviral gene transfer systems are attracting increasing interest. Their main advantages include low cost, ease of handling and large-scale production, large packaging capacity and, most importantly, biosafety. While nonviral gene transfer into HSCs has been restricted in the past by poor transfection efficiency and transient maintenance, in recent years, biotechnological developments are converting nonviral transfer into a realistic approach for genetic modification of cells of hematopoietic origin. Herein we provide an overview of past accomplishments in the field of nonviral gene transfer into hematopoietic progenitor/stem cells and we point at future challenges. We argue that episomally maintained self-replicating vectors combined with physical methods of delivery show the greatest promise among nonviral gene transfer strategies for the treatment of disorders of the hematopoietic system.

New tools for functional mammalian cancer genetics

Knowledge of the function of individual genes that encode components of cell-signalling pathways is crucial to our understanding of normal growth control and its deregulation in cancer, but we have functional information for only 15% of human genes at present. Several new technologies have recently become available to identify gene function in mammalian cells using high-throughput genetic screens. These new tools will make it possible to identify new and innovative classes of anticancer drugs, including those that show synthetic lethal interactions with cancer-specific mutations.

Establishment of an oriP/EBNA1-based episomal vector transcribing human genomic beta-globin in cultured murine fibroblasts

A novel oriP/EBNA1-based episomal vector has been constructed that persists episomally in cultured murine fibroblasts. The vector, pBH148, is equipped with the entire 185-kb human beta-globin gene locus. After amplification in bacteria, column-purified episomal pBH148 was transfected into both cultured EBNA1-expressing human D98/Raji positive control fusion cells (DRpBH148) and cultured EBNA1-negative murine fibroblast cells (A9pBH148). Cell cultures were maintained concurrently with and without hygromycin selection for a period of 3 months. We show long-term stable episome maintenance of the full-size 200-kb circular double-stranded pBH148 in both the DRpBH148 cultures and the A9pBH148 cultures, regardless of selective pressure by agarose gel electrophoresis and Southern blot. EBNA1 transgene was detected by PCR in all transfected cultures. In addition, we were able to detect correctly spliced human beta-globin mRNA by RT-PCR in all transfected late-passage DRpBH148 and A9pBH148 cell cultures. These findings illustrate that this oriP/EBNA1-based episomal vector is stable in a previously nonpermissive murine cell line and is a potential vector for human gene therapy.

Episomal vectors for gene expression in mammalian cells

An important reason for preferring mammalian cells for heterologous gene expression is their ability to make authentic proteins containing post-translational modifications similar to those of the native protein. The development of expression systems for mammalian cells has been ongoing for several years, resulting in a wide variety of effective expression vectors. The aim of this review is to highlight episomal expression vectors. Such episomal plasmids are usually based on sequences from DNA viruses, such as BK virus, bovine papilloma virus 1 and Epstein-Barr virus. In this review we will mainly focus on the improvements made towards the usefulness of these systems for gene expression studies and gene therapy.

Developments in expression cloning

Recent years have seen a dramatic expansion in the range of applications of expression cloning techniques. New vectors and detection methods promise to further broaden the applicability of function-based screening approaches to problems in gene discovery. A major theme in the past year has been the introduction of engineered reporter cells that heighten the sensitivity with which clones expressing cDNAs can be identified.