Interaction with a Kinesin‐2 Tail Propels Choline Acetyltransferase Flow Towards Synapse

Sadananda, Aparna; Hamid, Runa; Doodhi, Harinath; Ghosal, Debnath; Girotra, Mukul; Jana, Swadhin Chandra; Ray, Krishanu

doi:10.1111/j.1600-0854.2012.01361.x

Cited by 22 publications

(34 citation statements)

References 51 publications

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“…The latter is implicated in the assembly of T-bars marked by Bruchpilot at the presynaptic compartment (Tsurudome et al, 2010). The observed increase in the ChAT enrichment at the neuropile, which is transported by Kinesin-2 (Sadananda et al, 2012), is also consistent with this hypothesis. Further, the contents of the nascent Rab4-associated vesicles could regulate the membrane recycling at the nerve termini.…”

Section: Resultssupporting

confidence: 84%

“…4H–J; S3, Movie S4A). Previous reports showed that the KLP64DΔT forms a functional heterotrimeric motor complex (Sadananda et al, 2012). The presence of KLP64DΔT-GFP marginally improved the anterograde traffic as compared to the homozygous Klp64D −/− background.…”

Section: Resultsmentioning

confidence: 99%

“…Recent studies have, however, stated that the motor subunits could independently interact with soluble proteins through the tail domain (Girotra et al, 2016; Sadananda et al, 2012). Here, we showed that the Kinesin-2α tail could also bind to a membrane-associated protein, Rab4.…”

Section: Discussionmentioning

confidence: 99%

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Anterograde Transport of Rab4-Associated Vesicles Regulates Synapse Organization in Drosophila

2017

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Summary Local endosomal recycling at synapses is essential to maintain neurotransmission. Rab4GTPase, found on sorting endosomes, is proposed to balance the flow of vesicles between endocytic, recycling and degradative pathways in the presynaptic compartment. Here, we report that Rab4-associated vesicles move bidirectionally in Drosophila axons but with an anterograde bias, resulting in their moderate enrichment at the synaptic region of the larval ventral ganglion. Results from FRB-FKBP conjugation assays in rat embryonic fibroblasts together with genetic analyses in Drosophila indicate that an association with Kinesin-2 (mediated by the tail domain of Kinesin-2α/KIF3A/KLP64D subunit) moves Rab4-associated vesicles towards the synapse. Reduction in the anterograde traffic of Rab4 causes an expansion of the volume of the synapse-bearing region in the ventral ganglion and increases the motility of Drosophila larvae. These results suggest that Rab4-dependent vesicular traffic towards the synapse plays a vital role in maintaining synaptic balance in this neuronal network.

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Section: Resultssupporting

confidence: 84%

Section: Resultsmentioning

confidence: 99%

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Anterograde Transport of Rab4-Associated Vesicles Regulates Synapse Organization in Drosophila

2017

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“…FRAP kymographs indicate that both kinesin‐2 and tubulin are transported in the ciliary outer segment in a non‐particulate form. A similar recovery pattern was observed for the choline acetyltransferase in the axon . The latter directly binds to the C‐terminal tails of the kinesin‐2α subunit.…”

Section: Discussionmentioning

confidence: 94%

The C‐terminal tails of heterotrimeric kinesin‐2 motor subunits directly bind to α‐tubulin1: Possible implications for cilia‐specific tubulin entry

Girotra

Srivastava

Kulkarni

et al. 2017

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Funding informationTIFR, DAE, Government of India; DAE-SRC fellowship; UGC fellowship.The assembly of microtubule-based cytoskeleton propels the cilia and flagella growth. Previous studies have indicated that the kinesin-2 family motors transport tubulin into the cilia through intraflagellar transport. Here, we report a direct interaction between the C-terminal tail fragments of heterotrimeric kinesin-2 and α-tubulin1 isoforms in vitro. Blot overlay screen, affinity purification from tissue extracts, cosedimentation with subtilisin-treated microtubule and LC-ESI-MS/MS characterization of the tail-fragment-associated tubulin identified an association between the tail domains and α-tubulin1A/D isotype. The interaction was confirmed by Forster's resonance energy transfer assay in tissue-cultured cells. The overexpression of the recombinant tails in NIH3T3 cells affected the primary cilia growth, which was rescued by coexpression of a α-tubulin1 transgene. Furthermore, fluorescent recovery after photobleach analysis in the olfactory cilia of Drosophila indicated that tubulin is transported in a nonparticulate form requiring kinesin-2. These results provide additional new insight into the mechanisms underlying selective tubulin isoform enrichment in the cilia. K E Y W O R D Santenna, cilia, Drosophila, Kif3A, Kif3B, kinesin-like-protein 64D, kinesin-like-protein 68D, mouse

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“…Terada et al injected a bolus of fluorescently-labeled creatine kinase (a soluble protein conveyed in SCb) into the squid giant axon, and saw a slow anterogradely-biased movement of the labeled protein population at rates reminiscent of SCb (Terada et al, 2000, 2010). Using a drosophila model, Sadananda et al have also recently shown a kinesin-dependent slow, anterogradely-biased flow of the soluble protein choline acetyltransferase in axons (Sadananda et al 2012). Thus it appears that the biased flow of cytosolic cargoes in slow axonal transport is a conserved phenomenon, and collective efforts in different model-systems should provide clarity of underlying mechanisms in the future.…”

Section: Cargoes Moving In Fast and Slow Axonal Transportmentioning

confidence: 99%

Seeing the Unseen

Roy

2013

Neuroscientist

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Axonal transport is the lifeline of axons and synapses. After synthesis in neuronal cell-bodies, proteins are conveyed into axons in two distinct rate-classes – fast and slow axonal transport. While fast transport delivers vesicular cargoes, slow transport carries cytoskeletal and cytosolic (or soluble) proteins that have critical roles in neuronal structure and function. While significant progress has been made in dissecting the molecular mechanisms of fast vesicle-transport; mechanisms of slow axonal transport are still unclear. Why is this so? Historically, advances in the axonal transport field have mirrored innovations that allow visualization of the phenomena; and slow-transport cargoes are not as readily seen as motile vesicles. However, new ways of imaging slow transport have re-energized the field, and several such cargoes can now be visualized in living axons. This review first summarizes classic studies that characterized all transport components, and then discusses recent technical and conceptual advances in slow axonal transport that have provided insights into some long-standing mysteries.

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Interaction with a Kinesin‐2 Tail Propels Choline Acetyltransferase Flow Towards Synapse

Cited by 22 publications

References 51 publications

Anterograde Transport of Rab4-Associated Vesicles Regulates Synapse Organization in Drosophila

Anterograde Transport of Rab4-Associated Vesicles Regulates Synapse Organization in Drosophila

The C‐terminal tails of heterotrimeric kinesin‐2 motor subunits directly bind to α‐tubulin1: Possible implications for cilia‐specific tubulin entry

Seeing the Unseen

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