Genetic tools for imaging intracellular calcium dynamics in astrocytes

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6 These processes are likely downstream of extracellular signaling cascades which signal the astrocyte to modify its structure, gene expression and activity in response to changing extracellular conditions including pH, temperature, ionic makeup, and the presence of toxins or neurotransmitters (Rangroo Thrane et al., 2013; Schipke et al., 2008; Thrane et al., 2012). With the existence of highly evolved and effective GECIs, it is now possible to interrogate functional alterations in reactive astrocytes and to tease apart changes in complex interactions between astrocytes and neurons in the pathological brain. The unprecedented opportunity to dissect mechanisms of astrocytic contributions to disease has motivated this dissertation work. Objectives The objectives of this work were to build tools for imaging reactive astrocyte activity in the rat or mouse brain using the latest GECI-technology delivered via the least invasive methods possible. Rats have been frequently used throughout the history of neuroscience research. Thus, many behavioral and pathological rat brain models have been well characterized including the kainic acid model of status epilepticus and the 6-OHDA model of Parkinson's disease (Cenci et al., 2002; Jacob, 1999; Schultz, 1982; Williams et al., 2007). Unfortunately, methods for monitoring astrocyte calcium activity in rat models are limited. GECIs are often delivered to target tissues via viral vectors, but require invasive injections and are hampered by a low carrying capacity of less than 5 kb (Grieger and Samulski, 2005). Rat transgenic tools are still immature and require significant time and labor to develop. However, in utero electroporation (IUE) offers a valuable substitute for both of