Design and production of adeno-associated virus vectors for imaging mitochondrial networks in the brain

Abstract: Mitochondria are dynamic organelles that function in a complex interconnected network within the cell. Neurons are sensitive and highly energy demanding cells in the brain which require a functioning mitochondrial network that is able to provide ATP and modulate calcium. Mitochondrial networks have yet to be explored which gives rise to the need for specific and efficient molecular tools. In this project, I designed and produced adeno-associated virus vectors carrying a fluorescent reporter gene for imaging mitochondrial networks under human synapsin 1 promoter to target neurons specifically. The design of each vector was conducted with careful consideration of the different components in the plasmid design that are important for optimal expression, which resulted in two constructs; one self-complementary adeno-associated virus vector that marks the mitochondria and one single-stranded that marks mitochondria and the membrane of neurons.  The modularity of viral vectors allows the usage of different serotypes which adapt the vector to the cell type and the model. For this project I chose the serotypes 1 for neurons in vitro and PHP.eB which suits in vivo models since it has better permeability to the blood brain barrier. The production was conducted in human embryonic kidney cells using the triple-plasmid transfection method, followed by extraction and purification. The existence of viral particles was verified through transmission electron microscopy and the DNA titer of the vector through quantitative polymerase chain reaction. The produced adeno-associated virus vectors were delivered into young brain organoids which were not able to express the reporter gene, probably due to not fully developed neurons. The fluorescent protein expression targeting specifically mitochondria and the membrane was however verified in the human embryonic kidney cells during the packaging stages.