Ultrastructure-function properties of recycling synaptic vesicles in acute hippocampal slices

Synaptic vesicles are the substrate of neurotransmission in most nerve terminals in the central nervous system. These small membrane spheres fuse with the synaptic membrane in an activity-dependent manner and release neurotransmitter into the synaptic cleft. Subsequently, vesicles are reclaimed through endocytosis prior to reuse. This recycling process is key to supporting ongoing signalling in the brain. While substantial effort has gone into defining basic characteristics of vesicle recycling, for example elucidating the timing of vesicle turnover, key questions remain unanswered. An important area with significant knowledge deficits relates to the relationship between vesicle function and ultrastructural organisation in the terminal. The aim of this thesis is to address this issue, exploiting new methodologies which provide novel insights into function-structure relationships of vesicle populations in acute brain slices. Specifically, this study considers organisational principles of three defined vesicle pools as well as examining the impact of an established plasticity protocol on pool properties. The first results chapter, Chapter 3, outlines and validates the novel protocol used for fluorescently labelling functional recycling vesicle populations in acute rat brain slices using the vesicle-labelling dye FM1-43 and new antibody based probes (syt1-Oyster, CypHer5E). Reporter-labelling and release properties are compared to similar approaches using cultured neurons. We conclude that this approach provides a more physiologically relevant method to study the functional properties of cells than used previously in cultured neurons. Chapter 4 outlines experiments utilising the capability of FM 1-43 to be photoconverted to an electron-dense form to allow a defined vesicle population, the readily releasable