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OPEN ACCESS PLUS
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Contents
12(5): Pp. 410 - 416
Mahito Nakanishi and Makoto Otsu
[Open Access Plus] |
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Gene delivery/expression vectors have been used as fundamental technologies in gene therapy since the 1980s. These technologies are also being applied in regenerative medicine as tools to reprogram cell genomes to a pluripotent state and to other cell lineages. Rapid progress in these new research areas and expectations for their translation into clinical applications have facilitated the development of more sophisticated gene delivery/expression technologies. Since its isolation in 1953 in Japan, Sendai virus (SeV) has been widely used as a research tool in cell biology and in industry, but the application of SeV as a recombinant viral vector has been investigated only recently. Recombinant SeV vectors have various unique characteristics, such as low pathogenicity, powerful capacity for gene expression and a wide host range. In addition, the cytoplasmic gene expression mediated by this vector is advantageous for applications, in that chromosomal integration of exogenous genes can be undesirable. In this review, we introduce a brief historical background on the development of recombinant SeV vectors and describe their current applications in gene therapy. We also describe the application of SeV vectors in advanced nuclear reprogramming and introduce a defective and persistent SeV vector (SeVdp) optimized for such reprogramming.
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11(6): Pp. 479 - 484
Cevayir Coban, Kouji Kobiyama, Taiki Aoshi, Fumihiko Takeshita, Toshihiro Horii, Shizuo Akira and Ken J. Ishii
[Open Access Plus] |
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DNA vaccines can induce both humoral and cellular immune responses in animals. Some DNA vaccines are already licensed for infectious diseases such as West Nile virus encephalitis in horses. When used in humans, however, DNA vaccines suffer from lower immunogenicity profiles. Although the reasons for this are poorly understood, various hypotheses have been proposed. This review aims to provide better understanding of the molecular and immunological mechanisms by which DNA vaccines work and how such knowledge can be used to bring about improvements in their efficacy. Recent studies have provided evidence that the ‘adjuvant effect’ of plasmid DNA is mediated by its doublestranded structure. This structure activates stimulator of interferon genes/TANK-binding kinase 1 (STING/TBK1)- dependent innate immune signaling pathways in the absence of Toll-like receptors. Indeed, type-I interferons (IFNs), induced in vivo via the STING/TBK1 pathway, were found to be crucial for both direct- and indirect-antigen presentation via distinct cell types (i.e. dendritic cells (DC) and muscle cells, respectively). Importantly, incorporation of TBK1 into a DNA vaccine was found to enhance the antigen-specific humoral immune responses targeting the Plasmodium falciparum serine repeat antigen (SERA), a candidate vaccine antigen expressed in the blood-stages of human malaria parasites. Thus, the results of these studies may offer new ways to develop DNA vaccines, as well as delivering novel vaccine adjuvants against infectious diseases.
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11(4): Pp. 321 - 330
Federico Mingozzi and Katherine A. High
[Open Access Plus] |
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Findings in the first clinical trial in which an adeno-associated virus (AAV) vector was introduced into the liver of human subjects highlighted an issue not previously identified in animal studies. Upon AAV gene transfer to liver, two subjects developed transient elevation of liver enzymes, likely as a consequence of immune rejection of transduced hepatocytes mediated by AAV capsid-specific CD8+ T cells. Studies in healthy donors showed that humans carry a population of antigen-specific memory CD8+ T cells probably arising from wild-type AAV infections. The hypothesis formulated at that time was that these cells expanded upon re-exposure to capsid, i.e. upon AAV-2 hepatic gene transfer, and cleared AAV epitope-bearing transduced hepatocytes. Other hypotheses have been formulated which include specific receptorbinding properties of AAV-2 capsid, presence of capsid-expressing DNA in AAV vector preparations, and expression of alternate open reading frames from the transgene; emerging data from clinical trials however fail to support these competing hypotheses. Possible solutions to the problem are discussed, including the administration of a short-term immunosuppression regimen concomitant with gene transfer, or the development of more efficient vectors that can be administered at lower doses. While more studies will be necessary to define mechanisms and risks associated with capsid-specific immune responses in humans, monitoring of these responses in clinical trials will be essential to achieving the goal of longterm therapeutic gene transfer in humans.
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11(4): Pp. 241 - 258
Reeti Khare, Christopher Y. Chen, Eric A. Weaver and Michael A. Barry
[Open Access Plus] |
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Adenovirus is a robust vector for therapeutic applications, but its use is limited by our understanding of its complex in vivo pharmacology. In this review we describe the necessity of identifying its natural, widespread, and multifaceted interactions with the host since this information will be crucial for efficiently redirecting virus into target cells. In the rational design of vectors, the notion of overcoming a sequence of viral “sinks” must be combined with re-targeting to target populations with capsid as well as shielding the vectors from pre-existing or toxic immune responses. It must also be noted that most known adenoviral pharmacology is deduced from the most commonly used serotypes, Ad5 and Ad2. However, these serotypes may not represent all adenoviruses, and may not even represent the most useful vectors for all purposes. Chimeras between Ad serotypes may become useful in engineering vectors that can selectively evade substantial viral traps, such as Kupffer cells, while retaining the robust qualities of Ad5. Similarly, vectorizing other Ad serotypes may become useful in avoiding immunity against Ad5 altogether. Taken together, this research on basic adenovirus biology will be necessary in developing vectors that interact more strategically with the host for the most optimal therapeutic effect.
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11(3): Pp. 218 - 228
Youngsuk Yi, Moon Jong Noh and Kwan Hee Lee
[Open Access Plus] |
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There have been major changes since the incidents of leukemia development in X-SCID patients after the treatments using retroviral gene therapy. Due to the risk of oncogenesis caused by retroviral insertional activation of host genes, most of the efforts focused on the lentiviral therapies. However, a relative clonal dominance was detected in a patient with β-thalassemia Major, two years after the subject received genetically modified hematopoietic stem cells using lentiviral vectors. This disappointing result of the recent clinical trial using lentiviral vector tells us that the current and most advanced vector systems does not have enough safety. In this review, various safety features that have been tried for the retroviral gene therapy are introduced and the possible new ways of improvements are discussed. Additional feature of chromatin insulators, co-transduction of a suicidal gene under the control of an inducible promoter, conditional expression of the transgene only in appropriate target cells, targeted transduction, cell type-specific expression, targeted local administration, splitting of the viral genome, and site specific insertion of retroviral vector are discussed here.
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10(5): Pp. 341 - 349
J. Fraser Wright, Jennifer Wellman and Katherine A. High
[Open Access Plus] |
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Recombinant adeno-associated virus (AAV) -based vectors expressing therapeutic gene products have shown great promise for human gene therapy. A recent milestone has been the safety and efficacy observed using recombinant AAV2 expressing retinal pigment epithelial associated 65KDa protein for Leber Congenital Amaurosis. This review summarizes manufacturing and characterization of ‘AAV2-hRPE65v2’, the vector used in one completed Phase I/II clinical trial. Regulatory challenges and strategies that were successfully used for this groundbreaking trial are described.
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10(4): Pp. 287 - 299
Anita Gothelf and Julie Gehl
[Open Access Plus] |
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Gene electrotransfer, which designates the combination of gene transfer and electroporation, is a non-viral means for transfecting genes into cells and tissues. It is a safe and efficient method and reports regarding the use of this technique in a variety of animal models and organs have been published in the literature. We find that gene electrotransfer to skin is of particular interest; not only due to the easy accessibility of this organ, which renders both treatment and evaluation feasible, but also the capability of the skin to produce transgenes and elicit immunological responses. Up to now more than 40 papers have been published in which gene electrotransfer was the technique used for gene transfection to skin in vivo. The aim of this review is to summarize which plasmids were injected and the electrical parameters applied. Furthermore an overview of the clinical perspectives of gene electrotransfer to skin will be presented.
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9(6): Pp. 459 - 474
Katia Pauwels, Rik Gijsbers, Jaan Toelen, Axel Schambach, Karen Willard-Gallo, Celine Verheust, Zeger Debyser and Philippe Herman
[Open Access Plus] |
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Lentiviral vectors (LV) are competent gene transfer vehicles, as used for both research and gene therapy applications, because of their stable integration in non-dividing and dividing cells and long-term transgene expression. Along with our understanding that LV offer solutions for gene therapy, biosafety concerns have uncovered risks due to insertional mutagenesis, the generation of replication competent lentiviruses (RCL) and vector mobilization. Researchers therefore continue to devote significant efforts in designing LV with improved efficacy and biosafety features. The choice of a particular LV system for experimental studies is often driven by functional considerations, including increased productivity and/or transduction efficiency. The design of safer vectors has also directly benefited researchers allowing them to conduct experimental studies with lower risk. Currently, vectors combine improved safety features (that decrease the risk of recombination and vector mobilization) with increased transduction efficiency. Hence, risks associated with the inadvertent transduction of cells of the investigator gain greater importance in assessing the overall risk of these vectors and become an important biosafety concern. This review outlines the different strategies used to improve LV biosafety by comparing state-of-the-art and emerging LV production systems and highlighting biosafety issues that can arise during their contained use. The few existing national and international biosafety recommendations that specifically address the use of LV in research are discussed and recommendations for most common research activities using LV are proposed.
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9(3): Pp. 160 - 170
Sander W. Tas, Margriet J.B.M. Vervoordeldonk and Paul P. Tak
[Open Access Plus] |
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Nuclear factor (NF)-κB is regarded as one of the most important transcription factors and plays an essential role in the transcriptional activation of pro-inflammatory cytokines, cell proliferation and survival. NF-κB can be activated via two distinct NF-κB signal transduction pathways, the so-called canonical and non-canonical pathways, and has been demonstrated to play a key role in a wide range of inflammatory diseases and various types of cancer. Much effort has been put in strategies to inhibit NF-κB activation, for example by the development of pharmacological compounds that selectively inhibit NF-κB activity and therefore would be beneficial for immunotherapy of transplantation, autoimmune and allergic diseases, as well as an adjuvant approach in patients treated with chemotherapy for cancer. Gene therapy targeting NF-κB is a promising new strategy with the potential of long-term effects and has been explored in a wide variety of diseases, ranging from cancer to transplantation medicine and autoimmune diseases. In this review we discuss recent progress made in the development of NF-κB targeted gene therapy and the evolution towards clinical application.
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7(5): Pp. 316 - 324
Federico Mingozzi and Katherine A. High
[Open Access Plus] |
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Recent findings in a clinical trial in which an adeno-associated virus (AAV) vector expressing coagulation factor IX (F.IX) was introduced into the liver of hemophilia B subjects highlighted a new issue previously not identified in animal studies. Upon AAV gene transfer to liver, two subjects enrolled in this trial developed transient elevation of liver enzymes, likely as a consequence of immune rejection of transduced hepatocytes mediated by AAV capsid-specific CD8+ T cells. Studies in healthy donors showed that humans carry a population of antigen-specific memory CD8+ T cells probably arising from wild-type AAV infections. The hypothesis formulated here is that these cells expanded upon re-exposure to capsid, i.e. upon AAV-2 hepatic gene transfer, and cleared AAV epitope-bearing transduced hepatocytes. Other hypotheses have been formulated which include specific receptor-binding properties of AAV-2 capsid, presence of capsidexpressing DNA in AAV vector preparations, and expression of alternative reading frames from the transgene. Absence of a valid animal model has prevented an in-depth mechanistic study of the phenomenon. Several possible solutions to the problem are discussed, including the administration of a short-term anti-T cell immunosuppression regimen concomitant with gene transfer. While more studies will be necessary to further define mechanisms and risks associated with capsidspecific immune responses in humans, monitoring of these responses in clinical trials will be essential to achieving the goal of long-term therapeutic gene transfer in humans.
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7(3): Pp. 189 - 204
Samuel K. Campos and Michael A. Barry
[Open Access Plus] |
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Gene delivery vectors based on Adenoviral (Ad) vectors have enormous potential for the treatment of both hereditary and acquired disease. Detailed structural analysis of the Ad virion, combined with functional studies has broadened our knowledge of the structure/function relationships between Ad vectors and host cells/tissues and substantial achievement has been made towards a thorough understanding of the biology of Ad vectors. The widespread use of Ad vectors for clinical gene therapy is compromised by their inherent immunogenicity. The generation of safer and more effective Ad vectors, targeted to the site of disease, has therefore become a great ambition in the field of Ad vector development. This review provides a synopsis of the structure/function relationships between Ad vectors and host systems and summarizes the many innovative approaches towards achieving Ad vector targeting.
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6(3): Pp. 383 - 392
Kathlyn Santos, Cindy M.P. Duke and Stephen Dewhurst
[Open Access Plus] |
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HSV-1 amplicon vectors efficiently transduce cultured antigen-presenting cells (APC), including both human and murine dendritic cells as well as primary human chronic lymphocytic leukemia (CLL) B cells. Helper-free amplicons have been shown to be especially well-suited for this purpose, since they do not impair the antigen-presenting functions of these target cells. In vivo, amplicon vectors have been used in preclinical studies aimed at the development of therapeutic cancer vaccines, as well as vaccines for Alzheimers disease, and selected microbial pathogens. Studies in small animal model systems have shown that ex vivo transduction of irradiated tumor cells with amplicon vectors encoding immunomodulatory cytokines such as IL-2 or GM-CSF can elicit protective responses against a tumor challenge. In an experimental model for cancer immunotherapy, direct transduction of preformed tumors with vectors encoding CD40L resulted in slowed tumor growth or tumor eradication. Other studies have examined the ability of amplicons to elicit immune responses against encoded antigens, and have shown that strong cellular immune responses can be generated against amplicon encoded HIV-1 antigens in mice. Thus, amplicon vectors have shown significant promise as vaccine vectors in a range of settings. These promising initial findings highlight the need to perform additional studies, including experiments to evaluate the immunogenicity of amplicon vectors in additional animal models, possibly including nonhuman primates. Overall, amplicon vectors offer compelling advantages when compared to other vaccine-delivery platforms, which include the capacity to incorporate a very large transgene payload and the potential to efficiently transduce mucosal surfaces. It will be important to design future studies to directly test and exploit these features of the amplicon system. The next few years therefore promise to be an exciting and important period in the development of amplicons as vaccine vectors.
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6(2): Pp. 243 - 273
Gerald J. Prud'homme, Yelena Glinka, Amir S. Khan and Ruxandra Draghia-Akli
[Open Access Plus] |
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Nonviral gene transfer is markedly enhanced by the application of in vivo electroporation (also denoted electrogene transfer or electrokinetic enhancement). This approach is safe and can be used to deliver nucleic acid fragments, oligonucleotides, siRNA, and plasmids to a wide variety of tissues, such as skeletal muscle, skin and liver. In this review, we address the principles of electroporation and demonstrate its effectiveness in disease models. Electroporation has been shown to be equally applicable to small and large animals (rodents, dogs, pigs, other farm animals and primates), and this addresses one of the major problems in gene therapy, that of scalability to humans. Gene transfer can be optimized and tissue injury minimized by the selection of appropriate electrical parameters. We and others have applied this approach in preclinical autoimmune and/or inflammatory diseases to deliver either cytokines, anti-inflammatory agents or immunoregulatory molecules. Electroporation is also effective for the intratumoral delivery of therapeutic vectors. It strongly boost DNA vaccination against infectious agents (e.g., hepatitis B virus, human immunodeficiency virus-1) or tumor antigens (e.g., HER-2/neu, carcinoembryonic antigen). In addition, we found that electroporation-enhanced DNA vaccination against islet-cell antigens ameliorated autoimmune diabetes. One of the most likely future applications, however, may be in intramuscular gene transfer for systemic delivery of either endocrine hormones (e.g., growth hormone releasing hormone and leptin), hematopoietic factors (e.g., erythropoietin, GM-CSF), antibodies, enzymes, or numerous other protein drugs. In vivo electroporation has been performed in humans, and it seems likely it could be applied clinically for nonviral gene therapy.
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