Abstract: Given improvements in viral vector design, production and efficiency of transduction in the central nervous system (CNS), as well as increased knowledge of neuropathological mechanisms in neurological disorders, success in treating a CNS disorder with gene transfer seems inevitable. Several different vector systems have been studied extensively and the adeno-associated viral vector system has been utilized in most early stage clinical trials in neurological disorders. Other vector systems, such as lentivirus, adenovirus, and herpes simplex virus are also viable vector platforms that should fill significant clinical niches based on their specific characteristics. In addition to the choice of the appropriate vector, the proper choice of transgene for the appropriate strategy to treat a neurological disorder is also critical. The example of glial cell line-derived neurotrophic factor ligands to treat Parkinson's disease is used to illustrate the importance of the interface between interpretation of pre-clinical data and consideration of the natural history of the disorder. This interface dictates the proper design of clinical trials that are capable of testing whether the treatment is actually successful. ... Read more

Abstract: Human gene therapy has made substantial progress since the initiation of the first clinical trials 20 years ago. Here, we summarized important applications of gene transfer protocols in the treatment of various human diseases using different viral vectors. Recent successful trials on the treatment of ocular diseases and inherited immune deficiencies are particularly encouraging and have raised hopes that human gene therapy as a standard treatment option will finally become a reality. While immune responses and insertional mutagenesis pose obstacles for this novel form of molecular medicine, continuous progress suggests that a wider range of diseases can be treated with gene therapy in the future. ... Read more

Abstract: If those of us privileged enough to have the opportunity to work towards curing human diseases had the power to design the ideal therapeutic molecule, the question would be what selection criteria would we choose? Arguably, at the top of the list would be four mandatory properties: specificity, potency, tolerability, and universality. So it should come as no surprise the momentum associated with the field of small interfering RNA (siRNA)-induced RNA Interference (RNAi) therapeutics has gained strength, as these molecules have shown exceptional promise in fulfilling all of these requirements. Unfortunately, siRNAs are too large, too charged, and too rigid to passively diffuse across the cellular membrane and thereby require a delivery system to enter cells. Thus, since its conception of working in human cells, siRNA delivery remains THE 800 Pound Gorilla in the room. The main complication yet to overcome is engineering delivery systems that are safe and efficient in systemically delivering siRNA molecules to the diseased tissue and across the cellular membrane of target cells. Currently, encapsulating the siRNA in nanoparticle and liposomal systems has risen to become the standard of delivery approaches. While generally speaking these delivery platforms offer significant advancements, our laboratory is committed to generating alternative siRNA delivery technologies that avoid nanoparticle packaging and allow siRNA molecules to be delivered as single, soluble entities. This brief review discusses the first of these technologies, a Peptide Transduction Domain-dsRNA Binding Domain (PTD-DRBD) fusion protein that avidly binds to the siRNA backbone to mask the negative charge and uses the PTD for macromolecular cellular delivery. ... Read more

Abstract: Gene therapy for inherited retinal degeneration has made major advances toward the ultimate goal of reversing blindness in human patients. With significant advances in recombinant viral vector design, safety and efficacy profiles have greatly improved. Although these recent advances have been applied to many different retinal diseases, one retinal degenerative disease, Leber congenital amaurosis, appears to have the greatest potential for reversing blindness. In pre-clinical animal studies, gene therapy for Leber congenital amaurosis has demonstrated visual recovery. Recently, in landmark clinical trials, preliminary results have indicated safety and efficacy for the use of gene therapy in Leber congenital amaurosis, thus laying the foundation for continued use of gene therapy in other forms of inherited blinding disease. ... Read more

Abstract: Gene-directed enzyme prodrug therapy offers a new approach to treating some cancers. Clinical trials have been completed for brain and prostate cancers and the first product for post-surgical treatment of some brain tumors is awaiting marketing approval. Recent innovations provide a glimpse into the possible future evolution of a new gene medicine. ... Read more

Abstract: Despite the social stigma and manufacturing hurdles that come with using viruses as therapeutic tools, the molecular specificity offered by these bugs makes them too attractive to ignore. Still largely based on vaccines, viral vectors offer exciting tools to treat cancer or deliver specific genetic payloads to a desired tissue. Unfortunately, early clinical trials utilizing such vectors have been plagued with poor performance or even clinical toxicity most commonly associated with spurious genetic regulation and/or replication of the vector. Past efforts to control for unwanted toxicity have focused on modification of the receptor or use of tissue-specific genetic elements that added specificity to the transcriptional induction of the gene(s) of interest. While this has had some success, engineering receptors to control viral tropism often fails or results in a loss of replicative fitness. In addition, the use of tissue-specific promoter elements not only restricts the vector that can be used, bona fide small promoter elements are often not available for the desired target. With the caveats of viral vector-based therapeutics largely centered on a lack of in vivo control, the recent success of exploiting microRNA expression to limit viral tropism may breathe new life into the field. ... Read more

Abstract: Proteins produced by DNA recombinant technology have been playing important roles in modern medicine ever since the first such protein drug was approved by the U.S. Food and Drug Administration about three decades ago. However the inherent high cost of producing recombinant proteins, particularly those produced from mammalian cells, has hampered their broad application. Other protein expression systems that can reduce the cost yet still maintain the high-level therapeutic activities of the recombinant proteins are a top R&D priority. Eukaryotic unicellular green algae cells may provide a good solution to this long-standing challenge. ... Read more

Abstract: Hemophilia A is an X-linked bleeding disorder caused by defective coagulation Factor VIII (FVIII). Although the efficacies of existing treatment using purified or recombinant FVIII are good, there remain shortcomings in using this particular form of treatment. A few FVIII gene therapy clinical trials have been initiated with modest improvements recorded, but these are no longer being continued due to insufficient efficacy. However, with the progress in the development of gene delivery vectors and the availability of mouse and canine hemophilia A models, gene therapy of hemophilia A remains an area of hot pursuit. ... Read more

Abstract: The non-viral vectors and targeting methods offer some specific advantages. These include better safety profiles (lower toxicity and non-infectious properties) and the capacity to transfer large genes and low production costs. The clinical usefulness of non-viral methods has been hindered by their relatively low gene delivery and transgene expression efficiencies. However, recent problems in clinical trials using viral vectors renewed interest in non-viral technologies, particularly that the properties of non-viral vectors make them appear closer to the traditional pharmaceutics. ... Read more

Abstract: Molecular Trojan horses are genetically engineered proteins that cross the blood-brain barrier (BBB) via endogenous receptor-mediated transport processes. Molecular Trojan horses provide a brain drug targeting technology that allows for the non-invasive delivery of large molecule therapeutics to the human brain. The development of BBB drug targeting technology is an arcane area of discovery medicine that suffers from chronic under-development. ... Read more