Gene therapy for dentin regeneration with bone morphogenetic proteins

Recent advances in stem cell biology and gene therapy technology have provided the great potential of adult stem cells for therapeutic use in regeneration of lost tissue due to diseases including cancer, trauma, and even caries. Dental pulp tissues harbor mesenchymal stem/progenitor cells and have potential to regenerate and/or repair dentin-pulp complex after injury such as caries. There are two main methods, in vivo and ex vivo gene therapy. In in vivo gene therapy the healing potential of pulp tissue is enhanced by genes inducing dentin directly applied on the exposed/amputated dental pulp. In ex vivo gene therapy, pulp stem/progenitor cells transfected with some therapeutically proven genes to induce differentiation into odontoblasts which are transplanted on the exposed/amputated pulp. In the inflamed pulp under deep caries or trauma, possibly due to the limited supply of pulp stem/progenitor cells, it might be useful to apply cell-based ex vivo gene therapy compared to in vivo gene therapy. Before clinical use of ex vivo gene therapy for dentin regeneration in endodontics, there is a need for establishment of isolation, identification and expansion of the pulp stem cells. A safe and efficient gene delivery system also needs to be optimized. In this review we provide an overview of our current knowledge in the biology and function of adult pulp stem cells. This is followed by a discussion of the challenges of translating basic cellular and molecular biology of differentiation of pulp stem cells to safe and efficient gene therapy for dentin regeneration.     

Viral based gene therapy for prostate cancer

In the last few years, significant advances in gene therapy have been made as a result of advances in many areas of molecular and cell biology, including the improvement of both viral and nonviral gene delivery systems, discovery of new therapeutic genes, better understanding of mechanism of disease progression, exploration of tissue specific promoter, receptor- and antibody-mediated targeting delivery, and development of better prodrug enzyme/prodrug systems. In this article, viral based gene therapy for prostate cancer will be reviewed and discussed. The areas of emphasis in this review are: choice of viral vectors, comparison of delivery routes, development of prostate-targeted viruses, choice of therapeutic genes and strategies including corrective gene therapy (tumor suppressor gene and anti-oncogene gene approaches), suicide gene therapy, programmed cell death therapy, immunomodulation therapy, and conditional oncolytic virus approach. Among them, several examples will be discussed in detail for the scientific basis and therapeutic applications. In addition, prostate cancer gene therapy clinical trials, unresolved problems and future directions in this field will also be described.     

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.     

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.     

Muscular gene transfer using nonviral vectors

Skeletal muscle is a target tissue of choice for the gene therapy of both muscle and non-muscle disorders. Investigations of gene transfer into muscle have progressed considerably from the expression of plasmid reporter genes to the production of therapeutic proteins such as trophic factors, hormones, antigens, ion channels or cytoskeletal proteins. Viral vectors are intrinsically the most efficient vehicles to deliver genes into skeletal muscles. But, because viruses are associated with a variety of problems (such as immune and inflammatory responses, toxicity, limited large scale production yields, limitations in the size of the carried therapeutic genes), nonviral vectors remain a viable alternative. In addition, as nonviral vectors allow to transfer genetic structures of various sizes (including large plasmid DNA carrying full-length coding sequences of the gene of interest), they can be used in various gene therapy approaches. However, given the lack of efficiency of nonviral vectors in experimental studies and in the clinical settings, the overall outcome clearly indicates that improved synthetic vectors and/or delivery techniques are required for successful clinical gene therapy. Today, most of the potential muscle-targeted clinical applications seem geared toward peripheral ischemia (mainly through local injections) and cancer and infectious vaccines, and one locoregional administration of naked DNA in Duchenne muscular dystrophy. This review updates the developments in clinical applications of the various plasmid-based non-viral methods under investigation for the delivery of genes to muscles.     

Human artificial chromosome vectors meet stem cells

The recent emergence of stem cell-based tissue engineering has now opened up new venues for gene therapy. The task now is to develop safe and effective vectors that can deliver therapeutic genes into specific stem cell lines and maintain long-term regulated expression of these genes. Human artificial chromosomes (HACs) possess several characteristics that require gene therapy vectors, including a stable episomal maintenance, and the capacity for large gene inserts. HACs can also carry genomic loci with regulatory elements, thus allowing for the expression of transgenes in a genetic environment similar to the chromosome. Currently, HACs are constructed by a two prone approaches. Using a top-down strategy, HACs can be generated from fragmenting endogenous chromosomes. By a bottom-up strategy, HACs can be created de novo from cloned chromosomal components using chromosome engineering. This review describes the current advances in developing HACs, with the main focus on their applications and potential value in gene delivery, such as HAC-mediated gene expression in embryonic, adult stem cells, and transgenic animals.     

The translational imperative: Making cell therapy simple and effective

The current practice of cell therapy, in which multipotent or terminally differentiated cells are injected into tissues or intravenously, is inefficient. Few therapeutic cells are retained at the site of administration and engraftment is low. An injectable and biologically appropriate vehicle for delivery, retention, growth and differentiation of therapeutic cells is needed to improve the efficacy of cell therapy. We focus on a hyaluronan-based semi-synthetic extracellular matrix (sECM), HyStem®, which is a manufacturable, approvable and affordable clinical product. The composition of this sECM can be customized for use with mesenchymal stem cells as well as cells derived from embryonic or induced pluripotent sources. In addition, it can support therapeutic uses of progenitor and mature cell populations obtained from skin, fat, liver, heart, muscle, bone, cartilage, nerves and other tissues. This overview presents four pre-clinical uses of HyStem® for cell therapy to repair injured vocal folds, improve post-myocardial infarct heart function, regenerate damaged liver tissue and restore brain function following ischemic stroke. Finally, we address the real-world limitations – manufacture, regulation, market acceptance and financing – surrounding cell therapy and the development of clinical combination products.     

Electrotransfer into skeletal muscle for protein expression

An efficient and safe method to deliver DNA in vivo is a requirement for several purposes, such as study of gene function and gene therapy applications. Among the different non-viral delivery methods currently under investigation, in vivo DNA electrotransfer has proven to be one of the most efficient and simple. This technique is a physical method of gene delivery consisting in local application of electric pulses after DNA injection. Although this technique can be applied to almost any tissue of a living animal, including tumors, skin, liver, kidney, artery, retina, cornea or even brain, this review will focus on electrotransfer of plasmid DNA into skeletal muscle and its possible uses in gene therapy, vaccination, or functional studies. Skeletal muscle is a good target for electrotransfer of DNA as it is: a large volume easily accessible, an endocrine organ capable of expressing several local and systemic factors, and muscle fibres as post-mitotic cells have a long lifespan that allows long-term gene expression. In this review, we describe the mechanism of DNA electrotransfer, we assess toxicity and safety considerations related to this technique, and we focus on important therapeutic applications of electrotransfer demonstrated in animal models in recent years.     

Receptor-mediated interleukin-2 gene transfer into human hepatoma cells.

Receptor-mediated gene delivery is an attractive method for gene transfer in vitro and shows promise for in vivo gene therapy applications. In the current study, we have selected the cytokine interleukin-2 (IL-2) gene to explore the feasibility of receptor-mediated gene transfer into human hepatocellular carcinoma HepG2 cells, using Epstein-Barr virus (EBV)-based vectors. We have developed a targeted DNA delivery system for the treatment of liver cancer by gene therapy. This system utilizes the hepatocyte-specific asialoglycoprotein receptor, which is uniquely expressed on liver cell membranes but not present on other cell types. Galactosylated histone, a ligand to the asialoglycoprotein receptors, was synthesized, and a new EBV-based expression vector bearing the human IL-2 cDNA was constructed and conjugated to the ligand through ionic interactions. The ligand/IL-2 DNA complex was able to bind specifically to cell-surface receptors on the target cell and, when incubated with HepG2 cells, resulted in elevated levels of IL-2 gene expression. These results indicate that therapeutic genes like IL-2 in ligand/DNA complex can be transferred into hepatoma cells via the hepatocyte receptor. This study constitutes an encouraging first step in the assessment of receptor-mediated gene transfer as a technique for gene therapy in liver cancer.     

Transductional targeting with recombinant adenovirus vectors

Replication-deficient adenoviruses are considered as gene delivery vectors for the genetic treatment of a variety of diseases. The ability of such vectors to mediate efficient expression of therapeutic genes in a broad spectrum of dividing and non-dividing cell types constitutes an advantage over alternative gene transfer vectors. However, this broad tissue tropism may also turn disadvantageous when genes encoding potentially harmful proteins (e.g. cytokines, toxic proteins) are expressed in surrounding normal tissues. Therefore, specific restrictions of the viral tropism would represent a significant technological advance towards safer and more efficient gene delivery vectors, in particular for cancer gene therapy applications. In this review, we summarize various strategies used to selectively modify the natural tropism of recombinant adenoviruses. The advantages, limitations and potential impact on gene therapy operations of such modified vectors are discussed.     

Use of Interleukin- 2 in the Management of Haematological Malignancies

Somatic gene delivery approaches have received wide attention as a new technique for studying gene expression and as a potential therapeutic tool in treating both inherited and acquired diseases. Recent studies using nonviral and viral vectors have shown great promise for gene therapy in hypertensive diseases. Potential targets for prospective gene therapy in hypertension include vasopressor renin-angiotensin system components and a number of vasodilator polypeptides such as tissue kallikrein-kinin, atrial natriuretic peptide, adrenomedullin and nitric oxide synthase. Antisense inhibition with oligonucleotides or cDNAs encoding renin, angiotensinogen, angiotensin-converting enzyme and angiotensin receptors has been shown to cause a prolonged blood pressure reduction in spontaneously hypertensive rats. To evaluate the therapeutic potential of vasodilator proteins or peptides in high blood pressure, we delivered the genes encoding human tissue kallikrein, atrial natriuretic peptide, nitric oxide synthase, and adrenomedullin into hypertensive rat models and showed that a single injection resulted in a significant and sustained reduction of blood pressure for several weeks. The potency and duration of blood pressure reduction depends on the dose and the promoter of the gene administered, age and sex of the hypertensive animals as well as the vehicle used for gene delivery. Somatic gene transfer of human tissue kallikrein or atrial natriuretic peptide not only attenuated hypertension but also exerted a protective effect against salt-induced renal damage and cardiac hypertrophy in Dahl salt-sensitive rats after high salt loading. These results suggest that the application of antisense inhibition of vasopressors, or gene delivery of vasodepressors for gene therapy, may have potential in treating human hypertension, and cardiovascular and renal disorders.     

Gene therapy for osteoinduction

Various disorders of bone and mineral metabolism are diagnosed to be defective in genes related to cellular growth and differentiation. Gene therapy to introduce normal copy of defective genes into cells and tissues to compensate for silent, minimally expressed or mutated genes can be accomplished by multiple approaches. Although each bone disease/disorder would require a case-wise evaluation of potential strategies for best possible outcome, considerations for the gene therapy approaches are: 1) introduction of a therapeutic gene into cells without changing any of its native biological properties, 2) minimal or total absence of immunogenic and toxic effects from introduced vectors, genetically-modified cells or conditionally-expressed proteins, while achieving a therapeutic effect, 3) cell-type or tissue-specific, regulated expression of a therapeutic protein, and 4) restricting or abolishing the expression of disease triggering genes at the RNA or DNA levels. Although most of the currently available therapies for osteoinduction are pharmacological in nature, molecular understanding of biologically-driven factors provides greater opportunity to test their potential as therapeutic proteins. Strategies of gene therapy complement this approach through efficient delivery of genes encoding therapeutic proteins to target sites. The present review will attempt to give a comprehensive account of existing therapies for osteoinduction and discuss the potential and limitation of vector-mediated gene therapy for bone diseases.     

脂蛋白代谢紊乱和动脉粥样硬化基因治疗的现状

在人类进入后基因组时代的今天，基因治疗将会成为与各种遗传和大遗传疾病做斗争的一种有力武器。有效的基因治疗取决于对疾病发生分子机制的正确认识。随着对动脉粥样硬化发病机理认识的深入，一些分子靶点被逐步确认。其中系统靶点以降低低密度脂蛋白（LDL）和影响高密度脂蛋白（HDL）代谢为主，局部靶点则主要为抑制动脉壁平滑肌细胞增殖，局部抗血栓，抗氧化和促进血管内皮修复。针对这一系列靶点，有的基因需要高表达，的有基因则需要抑制，才能起到治疗作用。但是目前针对动脉粥样硬化的基因治疗还主要在实验研究阶段，向临床应用的过渡还有赖于基因载体系统的研发和最适动物模型的制备。本文对上述问题进行了较为详细的讨论。     

Gene therapy in tissue-engineered blood vessels

Cardiovascular disease is the leading cause of morbidity and mortality in Western society. More than 1 million arterial bypass procedures are performed annually in the United States, where either autologous veins or synthetic grafts are used to replace arteries in the coronary or peripheral circulation. Tissue engineering of blood vessels from autologous cells has the potential to produce biological grafts for use in bypass surgery. Ex vivo development of vascular grafts also provides an ideal target of site-specific gene therapy to optimize the physiology of the developing conduit, and for the possible delivery of other therapeutic genes to a vascular bed of interest. In this article, we demonstrate that by using a novel retroviral gene delivery system, a target gene of interest can be specifically delivered to the endothelial cells of a developing engineered vessel. Further, we demonstrate that this technique results in stable incorporation of the delivered gene into the target endothelial cells for more than 30 days. These data demonstrate the utility of the retroviral gene delivery approach for optimizing the biologic phenotype of engineered vessels. This also provides the framework for testing an array of genes that may improve the function of engineered blood vessels after surgical implantation.     

Orthopaedic applications of gene therapy

Current treatment modalities for musculoskeletal injuries due to disease or trauma often implement the use of tissue grafts, cell transplantations, and artificial scaffolding. These approaches may be augmented with the use of specific biological factors, which accelerate healthy tissue regeneration. Unfortunately, the short half-life and inherent instability of proteins requires the delivery of high doses or multiple doses of these molecules, neither of which is ideal for the patient or clinician. Gene therapy, as an alternative approach, has the potential to circumvent the existing limitations associated with protein delivery by producing a sustained release of the biologic agent at therapeutic levels. This is achieved by the direct transfer of the gene encoding the therapeutic agent to the cells of the afflicted tissue or by implanting cells that have been previously genetically modified in vitro. Using these methods, several laboratories have demonstrated the ability to deliver genes in vitro and in vivo resulting in accelerated and enhanced musculoskeletal tissue regeneration or inhibited disease progression. Many of these investigations, which involved bone, ligament, tendon, and cartilage, are covered in this review. Specifically, musculoskeletal tissue anatomy, factors relevant to musculoskeletal tissue regeneration, target cells, and in vivo and ex vivo gene therapy approaches for musculoskeletal regeneration are discussed. The experience and knowledge gained from these studies have affirmed gene therapy is a promising therapeutic strategy to combat musculoskeletal tissue repair and regeneration following disease or injury.     

Nonviral vectors for cancer gene therapy: prospects for integrating vectors and combination therapies

Gene therapy has the potential to improve the clinical outcome of many cancers by transferring therapeutic genes into tumor cells or normal host tissue. Gene transfer into tumor cells or tumor-associated stroma is being employed to induce tumor cell death, stimulate anti-tumor immune response, inhibit angiogenesis, and control tumor cell growth. Viral vectors have been used to achieve this proof of principle in animal models and, in select cases, in human clinical trials. Nevertheless, there has been considerable interest in developing nonviral vectors for cancer gene therapy. Nonviral vectors are simpler, more amenable to large-scale manufacture, and potentially safer for clinical use. Nonviral vectors were once limited by low gene transfer efficiency and transient or steadily declining gene expression. However, recent improvements in plasmid-based vectors and delivery methods are showing promise in circumventing these obstacles. This article reviews the current status of nonviral cancer gene therapy, with an emphasis on combination strategies, long-term gene transfer using transposons and bacteriophage integrases, and future directions.     

Gene therapeutic approaches for medullary thyroid carcinoma treatment

Medullary thyroid carcinoma (MTC), a neoplasm of thyroid C-cells, is characterized by dominant activating mutations in the RET proto-oncogene. Currently therapy is restricted to surgical removal of all neoplastic tissue lacking alternative forms of treatment such as chemotherapy or radiotherapy. Therefore MTC is a particularly attractive target for gene therapeutic approaches. Many promising gene therapy strategies have been used in various animal models of MTC, showing enhanced antitumoral efficacy, and these will hopefully extend our current standard of care in the future. These approaches can tentatively be subdivided into four groups: (a) Inhibition of oncogenic RET signaling, (b) suicide gene therapy, (c) immunotherapy, and (d) combination of immunotherapy and suicide approaches. To block oncogenic signal transduction dominant-negative RET mutants were delivered into tumor cells and found to possess strong antineoplastic activity, including tumor growth suppression and increased animal survival. Suicide gene therapeutic approaches applied to MTC treatment featured either gene transfer of herpes simplex virus thymidine kinase with concomitant application of ganciclovir or delivery of nitric oxide synthase II. Here antitumor effects were attributed to the occurrence of substantial bystander activities. Immunotherapy approaches comprised stimulation of immune response by delivery of interleukin 2 or 12. Finally, treatment with herpes simplex virus thymidine kinase/ganciclovir in combination with interleukin 2 was found to be superior over either treatment alone. This review discusses the various gene therapeutic approaches applied to MTC treatment in detail, gives an overview on the diverse vector systems used to achieve efficient transduction of thyroid cancer cells, and points out the strategies employed to accomplish target cell selective gene expression thereby contributing to enhanced safety of gene therapy for MTC     

Synthetic and natural polycations for gene therapy: state of the art and new perspectives

Currently, the major drawback of gene therapy is the gene transfection rate. The two main types of vectors that are used in gene therapy are based on viral or non-viral gene delivery systems. There are several non-viral systems that can be used to transfer foreign genetic material into the human body. In order to do so, the DNA to be transferred must escape the processes that affect the disposition of macromolecules. These processes include the interaction with blood components, vascular endothelial cells and uptake by the reticuloendothelial system. Furthermore, the degradation of therapeutic DNA by serum nucleases is also a potential obstacle for functional delivery to the target cell. Cationic polymers have a great potential for DNA complexation and may be useful as non-viral vectors for gene therapy applications. The objective of this review was to address the state of the art in gene therapy using synthetic and natural polycations and the latest strategies to improve the efficiency of gene transfer into the cell.