Tracking individual secretory vesicles during exocytosis reveals an ordered and regulated process.

Post-Golgi secretory vesicle trafficking is a coordinated process, with transport and regulatory mechanisms to ensure appropriate exocytosis. While the contributions of many individual regulatory proteins to this process are well studied, the timing and dependencies of events have not been defined. Here we track individual secretory vesicles and associated proteins in vivo during tethering and fusion in budding yeast. Secretory vesicles tether to the plasma membrane very reproducibly for ∼18 s, which is extended in cells defective for membrane fusion and significantly lengthened and more variable when GTP hydrolysis of the exocytic Rab is delayed. Further, the myosin-V Myo2p regulates the tethering time in a mechanism unrelated to its interaction with exocyst component Sec15p. Two-color imaging of tethered vesicles with Myo2p, the GEF Sec2p, and several exocyst components allowed us to document a timeline for yeast exocytosis in which Myo2p leaves 4 s before fusion, whereas Sec2p and all the components of the exocyst disperse coincident with fusion.

Head-to-tail regulation is critical for the in vivo function of myosin V.

Cell organization requires regulated cargo transport along cytoskeletal elements. Myosin V motors are among the most conserved organelle motors and have been well characterized in both yeast and mammalian systems. Biochemical data for mammalian myosin V suggest that a head-to-tail autoinhibitory interaction is a primary means of regulation, but the in vivo significance of this interaction has not been studied. Here we generated and characterized mutations in the yeast myosin V Myo2p to reveal that it is regulated by a head-to-tail interaction and that loss of regulation renders the myosin V constitutively active. We show that an unregulated motor is very deleterious for growth, resulting in severe defects in Myo2-mediated transport processes, including secretory vesicle transport, mitochondrial inheritance, and nuclear orientation. All of the defects associated with motor misregulation could be rescued by artificially restoring regulation. Thus, spatial and temporal regulation of myosin V in vivo by a head-to-tail interaction is critical for the normal delivery functions of the motor.

Myosin-V is activated by binding secretory cargo and released in coordination with Rab/exocyst function.

Cell organization requires motor-dependent transport of specific cargos along cytoskeletal elements. How the delivery cycle is coordinated with other events is poorly understood. Here we define the in vivo delivery cycle of myosin-V in its essential function of secretory vesicle transport along actin cables in yeast. We show that myosin-V is activated by binding a secretory vesicle and that myosin-V mutations that compromise vesicle binding render the motor constitutively active. About ten motors associate with each secretory vesicle for rapid transport to sites of cell growth. Once transported, the motors remain associated with the secretory vesicles until they undergo exocytosis. Motor release is temporally regulated by vesicle-bound Rab-GTP hydrolysis and requires vesicle tethering by the exocyst complex but does not require vesicle fusion with the plasma membrane. All components of this transport cycle are conserved in vertebrates, so these results should be generally applicable to other myosin-V delivery cycles.

A role for phospholipase A2 activity in membrane tubule formation and TGN trafficking.

We have investigated the role of phospholipase A(2) (PLA(2) ) enzymes in generating membrane tubules at the trans-Golgi network (TGN). Constitutive TGN membrane tubules and those induced by over-expressing kinase dead protein kinase D were inhibited by the PLA(2) inhibitors ONO-RS-082 (ONO) and bromoenol lactone. These antagonists also inhibited secretory delivery of both soluble and transmembrane cargoes. Finally, use of the reversible antagonist ONO and time-lapse imaging revealed for the first time that PLA(2) antagonists inhibit the initiation of membrane tubule formation at the TGN. Thus, PLA(2) enzymes appear to have an important role in the earliest steps of membrane tubule formation at the TGN, which are utilized for membrane trafficking.