Abstract
The Saccharomyces cerevisiae myosin-V, Myo2p, is essential for polarized growth, most likely through transport of secretory vesicles to the developing bud. Myo2p is also required for vacuole movement, a process not essential for growth. The globular region of the myosin-V COOH-terminal tail domain is proposed to bind cargo. Through random mutagenesis of this globular tail, we isolated six new single point mutants defective in vacuole inheritance, but not polarized growth. These point mutations cluster to four amino acids in an 11-amino acid span, suggesting that this region is important for vacuole movement. In addition, through characterization of myo2-DeltaAflII, a deletion of amino acids 1,459-1,491, we identified a second region of the globular tail specifically required for polarized growth. Whereas this mutant does not support growth, it complements the vacuole inheritance defect in myo2-2 (G1248D) cells. Moreover, overexpression of the myo2-DeltaAflII globular tail interferes with vacuole movement, but not polarized growth. These data indicate that this second region is dispensable for vacuole movement. The identification of these distinct subdomains in the cargo-binding domain suggests how myosin-Vs can move multiple cargoes. Moreover, these studies suggest that the vacuole receptor for Myo2p differs from the receptor for the essential cargo.
Highlights
Myosin-V is an actin-based motor protein involved in polarized organelle movement
An 11-Amino Acid Region of the Globular Tail Is Critical for Vacuole Inheritance myo2-2 (G1248D), a point mutation in the globular tail domain of Myo2p, causes defects in vacuole inheritance and association with the vacuole (Catlett and Weisman, 1998)
In wild-type cells, Proproteinase B (proPrB) activation continues for many generations after the loss of the PEP4 gene, due to PrB that is partitioned with the vacuole (Jones, 1991; Gomes de Mesquita et al, 1996)
Summary
Myosin-V is an actin-based motor protein involved in polarized organelle movement. Analysis of myosin-V mutants in a variety of organisms suggests it is a multifunctional motor, involved in the transport of several cargo organelles. Loss of myosin Va in humans (Griscelli syndrome) or mice (dilute) causes lightened pigmentation and neurological defects, including seizures (Mercer et al, 1991; Pastural et al, 1997; Mancini et al, 1998). Analysis of dilute mutants suggests that the pigmentation defect is due to impaired transport of melanosomes, pigment-containing lysosomal organelles, to the periphery of melanocytes (Provance et al, 1996; Wei et al, 1997). Griscelli syndrome patients suffer from immune dysfunction, presumably due to impaired transport of addi-
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