Adeno-Associated Virus-Mediated Gene Delivery for the Treatment of Amyotrophic Lateral Sclerosis and other Motor Neuron Disorders

The delivery of molecules and genes to the central nervous system (CNS) poses a major challenge for the treatment of neurodegenerative diseases. CNS disorders require long-term intervention and the presence of the blood-brain barrier (BBB) restricts the penetration of conventional drugs to the desired target cells. One approach towards stable delivery of therapeutic agents to the CNS is based on the transfer of DNA to target cells using viral vectors; a strategy known as gene therapy. Although viral vectors have provided encouraging results in CNS gene therapy trials for disorders such as Parkinson's disease, the small diffusion of the vector following direct injection into the brain region is not amenable to motor neuron (MN) disorders, such as amyotrophic lateral sclerosis (ALS) and spinal muscular atrophy, that have cells distributed across fifty centimeters of spinal cord. The aim of this thesis was to explore non-invasive approaches for gene delivery to MNs of the spinal cord using adeno-associated viruses (AAV). AAV vectors are powerful gene transfer vehicles due to their low pathogenicity and ability to express genes in neurons for long periods of time. The first part of the thesis focused on ALS, an incurable paralytic disease resulting from a global death of MNs. Using a mouse model of ALS expressing a mutant form of superoxide dismutase 1 (SOD1) that causes the disease in humans, we have delivered genetic silencing instructions that act to degrade the SOD1 messenger RNA prior to its translation into the toxic protein. AAV serotype 6 was used to deliver the SOD1-silencing cassette through noninvasive peripheral routes to target relevant cell types in disease. The vector was administered intravenously following the hypothesis that AAV could infect MNs from the vasculature through traversing the peripheral axons that connect the MNs to the muscle fibers, a process known as retrograde transport. This resulted in infection of MNs across the spinal cord and brain stem, as well as almost total infection of skeletal muscle, another cell type implicated in ALS. Direct injections into multiple muscle groups were also performed, capitalizing on the retrograde transport capability of AAVs, to result in even higher levels of MN infection. These injections demonstrated that AAV serotype 6 could successfully deliver genes to MNs across the breadth of the spinal cord and resulted in protection of individual MN pools from ALS-mediated death. Curiously, however, despite the impressive infection profiles and neuroprotection at various spinal cord levels, neither of the techniques altered the disease course of the animals. These results stress the complexity of gene delivery and suggest that critical thresholds of SOD1-silencing and transduction across various cell types are required to rescue this particular disease model. The second component of the thesis concentrated purely on gene delivery to spinal cord neurons. AAV serotype 6 was injected directly i