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Abstract
Axonal extension and synaptic targeting are usually completed during early development, but the axonal length and synaptic integrity need to be actively maintained during later developmental stages and the adult life. Failure in the axonal length maintenance and the subsequent axonal degeneration have been associated with neurological disorders, but currently little is known about the genetic factors controlling this process. Here, we show that regulated intracellular levels of cAMP-dependent protein kinase A (PKA) are critical for the axon maintenance during the transition from the early to the later larval stages in the Drosophila class IV dendritic arborization (da) sensory neurons. Our data indicate that when the intracellular levels of PKA are increased via genetic manipulations, these peripheral neurons initially form synapses with wild-type appearance, at their predicted ventral nerve cord (VNC) target sites (in the first and second instar larval stages), but that their synapses disintegrate, and the axons retract and become fragmented in the subsequent larval stages (third larval stage). The affected axonal endings at the disintegrated synaptic sites still express the characteristic presynaptic and cytoskeletal markers such as Bruchpilot and Fascin, indicating that the synapse had been initially properly formed, but that it later lost its integrity. Finally, the phenotype is significantly more prominent in the axons of the neurons whose cell bodies are located in the posterior body segments. We propose that the reason for this is the fact that during the larval development the posterior neurons face a much greater challenge while trying to keep up with the fast-paced growth of the larval body, and that PKA is critical for this process. Our data reveal PKA as a novel factor in the axonal length and synapse integrity maintenance in sensory neurons. These results could be of help in understanding neurological disorders characterized by destabilized synapses.
Acknowledgements
TC would like to thank Christos Delidakis for his generous support in terms of both providing the lab space and reagents at IMBB-FORTH (Herlaklion, Crete, Greece) as well as the intellectual input during the early stage of the project. Some preliminary data were also obtained in the laboratory of Wes Grueber at the Columbia University (New York, USA). We would like to thank Bloomington Drosophila Stock Center at Indiana University for providing fly stocks, as well as the following individual labs for sharing their fly lines with us: Sofia Araujo, Stephan Sigrist, Bassem Hassan, Brian Stramer, Daniel Kalderon, and Yuh Nung Jan. The a-Futsch antibody (mAb 22C10) was provided by the Developmental Studies Hybridoma Bank (Iowa University).
Disclosure statement
No potential conflict of interest was reported by the authors.