1,721,180 research outputs found
Why do we need new gene therapy viral vectors? Characteristics, limitations and future perspectives of viral vector transduction
No full textThe use of viruses to transduce genes of interest into mammalian cells has been extremely revolutionary, both in terms of laboratory research and for clinical purposes. This approach has allowed expression and over-expression of proteins of interest as well as the understanding of both virus life cycles and eukaryotic cell mechanisms. Beginning in the late eighties gene transduction has been applied to clinical trials but mainly restricted to cancer treatment and genetic diseases. More recently it has been proposed for the cure of infectious diseases (AIDS), vascular diseases and others (Alzheimer's and Parkinson's disease). Viral vectors have been progressively modified in order to increase their transduction efficiency and to reduce their toxicity, immunogenicity and inflammatory potential. In this respect, much has been done in the last few years. By adding genes belonging to other viral species to the vectors' DNA, scientists were able to re-direct their tissue-specificity or to control protein expression. More recently, in the attempt of overcoming the limitations of each viral species, so-called chimeric viral vectors have been generated by combining favourable features of two or more different viruses into one. This review summarises the main characteristics of the most common viral vectors, including their advantages, limitations and possible future applications. It also briefly discusses development and evolution of chimeric vectors, treated in more details along this entire issue. Finally, we evaluate basic safety aspects, mandatory to consider for the clinical application of viral gene transduction
Pathophysiology of neuropathic lysosomal storage disorders
No full textAlthough neurodegenerative diseases are most prevalent in the elderly, in rare cases, they can also affect children. Lysosomal storage diseases (LSDs) are a group of inherited metabolic neurodegenerative disorders due to deficiency of a specific protein integral to lysosomal function, such as enzymes or lysosomal components, or to errors in enzyme trafficking/targeting and defective function of nonenzymatic lysosomal proteins, all preventing the complete degradation and recycling of macromolecules. This primary metabolic event determines a cascade of secondary events, inducing LSD's pathology. The accumulation of intermediate degradation affects the function of lysosomes and other cellular organelles. Accumulation begins in infancy and progressively worsens, often affecting several organs, including the central nervous system (CNS). Affected neurons may die through apoptosis or necrosis, although neuronal loss usually does not occur before advanced stages of the disease. CNS pathology causes mental retardation, progressive neurodegeneration, and premature death. Many of these features are also found in adult neurodegenerative disorders, such as Alzheimer's, Parkinson's, and Huntington's diseases. However, the nature of the secondary events and their exact contribution to mental retardation and dementia remains largely unknown. Recently, lysosomal involvement in the pathogenesis of these disorders has been described. Improved knowledge of secondary events may have impact on diagnosis, staging, and follow-up of affected children. Importantly, new insights may provide indications about possible disease reversal upon treatment. A discussion about the CNS pathophysiology involvement in LSDs is the aim of this review. The lysosomal involvement in adult neurodegenerative diseases will also be briefly described
Neuronopathic lysosomal storage disorders: Approaches to treat the central nervous system
No full textPharmacological research has always focused on developing new therapeutic strategies capable of modifying a disease's natural history and improving patients' quality of life. Despite recent advances within the fields of medicine and biology, some diseases still represent a major challenge for successful therapy. Neuronopathic lysosomal storage disorders, in particular, have high rates of morbidity and mortality and a devastating socio-economic effect. Many of the available therapies, such as enzyme replacement therapy, can reverse the natural history of the disease in peripheral organs but, unfortunately, are still unable to reach the central nervous system effectively because they cannot cross the blood-brain barrier that surrounds and protects the brain. Moreover, many lysosomal storage disorders are characterized by a number of blood-brain barrier dysfunctions, which may further contribute to disease neuropathology and accelerate neuronal cell death. These issues, and their context in the development of new therapeutic strategies, will be discussed in detail in this chapter
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