Calsyntenin-1 and calsyntenin-3 coordinate TGN exit of axonal cargoes
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Neurons rely on precise biosynthetic protein transport from the soma to the axon and dendrites. Brain-enriched calsyntenins (CSTN1–3) are unique transmembrane adaptors that link cargo to kinesin-1 for transport. Yet, the neuronal distribution and interdependence of the three CSTN paralogs remain unclear. Here, we dissected their subcellular localization and contribution to biosynthetic protein transport. CSTN paralogs were predominantly localized to the TGN and axonal vesicles, with CSTN1 and CSTN3 showing higher expression levels than CSTN2. Depletion of either CSTN1 or CSTN3 affected axonal abundance of the other, suggesting that they function within the same pathway. Consistently, knockdown of CSTN1 or CSTN3, but not CSTN2, impaired the TGN exit and transport of multiple biosynthetic cargoes to the axon. Interestingly, most CSTN-positive vesicles exiting the TGN and in the axon were marked by the biosynthetic trafficking regulator RAB6A. Furthermore, we identified opposing, paralog-specific roles of CSTN1 and CSTN3 in regulating RAB6A levels at the TGN, thereby contributing to Golgi organization and axonal trafficking. Loss of CSTN1 reduced RAB6A and induced Golgi compaction, whereas loss of CSTN3 increased RAB6A and promoted Golgi dispersal. Together, we reveal that CSTN1 and CSTN3 have distinct, yet intersecting roles in the regulation of biosynthetic axonal transport.