Presenilin influences glycogen synthase kinase-3 ß (GSK-3ß) for kinesin-1 and dynein function during axonal transport.

Within axons, molecular motors transport essential components required for neuronal growth and viability. Although many levels of control and regulation must exist for proper anterograde and retrograde transport of vital proteins, little is known about these mechanisms. We previously showed that presenilin (PS), a gene involved in Alzheimer's disease (AD), influences kinesin-1 and dynein function in vivo. Here, we show that these PS-mediated effects on motor protein function are via a pathway that involves glycogen synthase kinase-3ß (GSK-3ß). PS genetically interacts with GSK-3ß in an activity-dependent manner. Excess of active GSK-3ß perturbed axonal transport by causing axonal blockages, which were enhanced by reduction of kinesin-1 or dynein. These GSK-3ß-mediated axonal defects do not appear to be caused by disruptions or alterations in microtubules (MTs). Excess of non-functional GSK-3ß did not affect axonal transport. Strikingly, GSK-3ß-activity-dependent axonal transport defects were enhanced by reduction of PS. Collectively, our findings suggest that PS and GSK-3ß are required for normal motor protein function. Our observations propose a model, in which PS likely plays a role in regulating GSK-3ß activity during transport. These findings have important implications for our understanding of the complex regulatory machinery that must exist in vivo and how this system is coordinated during the motility of vesicles within axons.

Visualization of larval segmental nerves in 3(rd) instar Drosophila larval preparations.

Drosophila melanogaster is emerging as a powerful model system for studying the development and function of the nervous system, particularly because of its convenient genetics and fully sequenced genome. Additionally, the larval nervous system is an ideal model system to study mechanisms of axonal transport as the larval segmental nerves contain bundles of axons with their cell bodies located within the brain and their nerve terminals ending along the length of the body. Here we describe the procedure for visualization of synaptic vesicle proteins within larval segmental nerves. If done correctly, all components of the nervous system, along with associated tissues such as muscles and NMJs, remain intact, undamaged, and ready to be visualized. 3(rd) instar larvae carrying various mutations are dissected, fixed, incubated with synaptic vesicle antibodies, visualized and compared to wild type larvae. This procedure can be adapted for several different synaptic or neuronal antibodies and changes in the distribution of a variety of proteins can be easily observed within larval segmental nerves.