scAAV9 intracisternal delivery results in efficient gene transfer to the central nervous system of a feline model of motor neuron disease.

On the basis of previous studies suggesting that vascular endothelial growth factor (VEGF) could protect motor neurons from degeneration, adeno-associated virus vectors (serotypes 1 and 9) encoding VEGF (AAV.vegf) were administered in a limb-expression 1 (LIX1)-deficient cat-a large animal model of lower motor neuron disease-using three different delivery routes to the central nervous system. AAV.vegf vectors were injected into the motor cortex via intracerebral administration, into the cisterna magna, or intravenously in young adult cats. Intracerebral injections resulted in detectable transgene DNA and transcripts throughout the spinal cord, confirming anterograde transport of AAV via the corticospinal pathway. However, such strategy led to low levels of VEGF expression in the spinal cord. Similar AAV doses injected intravenously resulted also in poor spinal cord transduction. In contrast, intracisternal delivery of AAV exhibited long-term transduction and high levels of VEGF expression in the entire spinal cord, yet with no detectable therapeutic clinical benefit in LIX1-deficient animals. Altogether, we demonstrate (i) that intracisternal delivery is an effective AAV delivery route resulting in high transduction of the entire spinal cord, associated with little to no off-target gene expression, and (ii) that in a LIX1-deficient cat model, however, VEGF expressed at high levels in the spinal cord has no beneficial impact on the disease course.

Neonatal systemic delivery of scAAV9 in rodents and large animals results in gene transfer to RPE cells in the retina.

Systemic delivery of recombinant adeno-associated virus (rAAV) vectors has recently been shown to cross the blood brain barrier in rodents and large animals and to efficiently target cells of the central nervous system. Such approach could be particularly interesting to treat lysosomal storage diseases or neurodegenerative disorders characterized by multiple organs injuries especially neuronal and retinal dysfunctions. However, the ability of rAAV vector to cross the blood retina barrier and to transduce retinal cells after systemic injection has not been precisely determined. In this study, gene transfer was investigated in the retina of neonatal and adult rats after intravenous injection of self-complementary (sc) rAAV serotype 1, 5, 6, 8, and 9 carrying a CMV-driven green fluorescent protein (GFP), by fluorescence fundus photography and histological examination. Neonatal rats injected with scAAV2/9 vector displayed the strongest GFP expression in the retina, within the retinal pigment epithelium (RPE) cells. Retinal tropism of scAAV2/9 vector was further assessed after systemic delivery in large animal models, i.e., dogs and cats. Interestingly, efficient gene transfer was observed in the RPE cells of these two large animal models following neonatal intravenous injection of the vector. The ability of scAAV2/9 to transduce simultaneously neurons in the central nervous system, and RPE cells in the retina, after neonatal systemic delivery, makes this approach potentially interesting for the treatment of infantile neurodegenerative diseases characterized by both neuronal and retinal damages.