Kan Hong Zheng scite author profile

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-3β (GSK-3β). PS genetically interacts with GSK-3β in an activity-dependent manner. Excess of active GSK-3β perturbed axonal transport by causing axonal blockages, which were enhanced by reduction of kinesin-1 or dynein. These GSK-3β-mediated axonal defects do not appear to be caused by disruptions or alterations in microtubules (MTs). Excess of non-functional GSK-3β did not affect axonal transport. Strikingly, GSK-3β-activity-dependent axonal transport defects were enhanced by reduction of PS. Collectively, our findings suggest that PS and GSK-3β are required for normal motor protein function. Our observations propose a model, in which PS likely plays a role in regulating GSK-3β 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.

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Huntingtin differentially regulates the axonal transport of a sub-set of Rab-containing vesiclesin vivo

White

Anderson

Zimmerman

et al. 2015

Hum. Mol. Genet.

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Loss of huntingtin (HTT), the Huntington's disease (HD) protein, was previously shown to cause axonal transport defects. Within axons, HTT can associate with kinesin-1 and dynein motors either directly or via accessory proteins for bi-directional movement. However, the composition of the vesicle-motor complex that contains HTT during axonal transport is unknown. Here we analyze the in vivo movement of 16 Rab GTPases within Drosophila larval axons and show that HTT differentially influences the movement of a particular sub-set of these Rab-containing vesicles. While reduction of HTT perturbed the bi-directional motility of Rab3 and Rab19-containing vesicles, only the retrograde motility of Rab7-containing vesicles was disrupted with reduction of HTT. Interestingly, reduction of HTT stimulated the anterograde motility of Rab2-containing vesicles. Simultaneous dual-view imaging revealed that HTT and Rab2, 7 or 19 move together during axonal transport. Collectively, our findings indicate that HTT likely influences the motility of different Rab-containing vesicles and Rab-mediated functions. These findings have important implications for our understanding of the complex role HTT plays within neurons normally, which when disrupted may lead to neuronal death and disease.

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The Non-amyloidal Component Region of α-Synuclein Is Important for α-Synuclein Transport Within Axons

Anderson

Hirpa

Zheng

et al. 2020

Front. Cell. Neurosci.

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Proper transport of the Parkinson's disease (PD) protein, α-synuclein (α-syn), is thought to be crucial for its localization and function at the synapse. Previous work has shown that defects in long distance transport within narrow caliber axons occur early in PD, but how such defects contribute to PD is unknown. Here we test the hypothesis that the NAC region is involved in facilitating proper transport of α-syn within axons via its association with membranes. Excess α-syn or fPD mutant α-syn A53T accumulates within larval axons perturbing the transport of synaptic proteins. These α-syn expressing larvae also show synaptic morphological and larval locomotion defects, which correlate with the extent of α-syn-mediated axonal accumulations. Strikingly, deletion of the NAC region (α-syn 71−82) prevented α-syn accumulations and axonal blockages, and reduced its synaptic localization due to decreased axonal entry and axonal transport of α-syn, due to less α-syn bound to membranes. Intriguingly, co-expression α-syn 71−82 with full-length α-syn rescued α-syn accumulations and synaptic morphological defects, and decreased the ratio of the insoluble higher molecular weight (HMW)/soluble low molecular weight (LMW) α-syn, indicating that this region is perhaps important for the dimerization of α-syn on membranes. Together, our observations suggest that under physiological conditions, α-syn associates with membranes via the NAC region, and that too much α-syn perturbs axonal transport via aggregate formation, instigating synaptic and behavioral defects seen in PD.

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Kan Hong Zheng

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

Huntingtin differentially regulates the axonal transport of a sub-set of Rab-containing vesiclesin vivo

The Non-amyloidal Component Region of α-Synuclein Is Important for α-Synuclein Transport Within Axons

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