Isolation and characterization of yeast mutants in the cytoplasm to vacuole protein targeting pathway.

In Saccharomyces cerevisiae the vacuolar protein aminopeptidase I (API) is localized to the vacuole independent of the secretory pathway. The alternate targeting mechanism used by this protein has not been characterized. API is synthesized as a 61-kD soluble cytosolic precursor. Upon delivery to the vacuole, the amino-terminal propeptide is removed by proteinase B (PrB) to yield the mature 50-kD hydrolase. We exploited this delivery-dependent maturation event in a mutant screen to identify genes whose products are involved in API targeting. Using antiserum to the API propeptide, we isolated mutants that accumulate precursor API. These mutants, designated cvt, fall into eight complementation groups, five of which define novel genes. These five complementation groups exhibit a specific defect in maturation of API, but do not have a significant effect on vacuolar protein targeting through the secretory pathway. Localization studies show that precursor API accumulates outside of the vacuole in all five groups, indicating that they are blocked in API targeting and/or translocation. Future analysis of these gene products will provide information about the subcellular components involved in this alternate mechanism of vacuolar protein localization.

Multiple classes of yeast mutants are defective in vacuole partitioning yet target vacuole proteins correctly.

In Saccharomyces cerevisiae the vacuoles are partitioned from mother cells to daughter cells in a cell-cycle-coordinated process. The molecular basis of this event remains obscure. To date, few yeast mutants had been identified that are defective in vacuole partitioning (vac), and most such mutants are also defective in vacuole protein sorting (vps) from the Golgi to the vacuole. Both the vps mutants and previously identified non-vps vac mutants display an altered vacuolar morphology. Here, we report a new method to monitor vacuole inheritance and the isolation of six new non-vps vac mutants. They define five complementation groups (VAC8-VAC12). Unlike mutants identified previously, three of the complementation groups exhibit normal vacuolar morphology. Zygote studies revealed that these vac mutants are also defective in intervacuole communication. Although at least four pathways of protein delivery to the vacuole are known, only the Vps pathway seems to significantly overlap with vacuole partitioning. Mutants defective in both vacuole partitioning and endocytosis or vacuole partitioning and autophagy were not observed. However, one of the new vac mutants was additionally defective in direct protein transport from the cytoplasm to the vacuole.

Genetic and phenotypic overlap between autophagy and the cytoplasm to vacuole protein targeting pathway.

We have explored the phenotypic and genetic overlap between autophagocytosis and cytoplasm to vacuole targeting in the yeast Saccharomyces cerevisiae. Complementation analysis was performed with mutants in each of these groups (aut and cvt, respectively), and three complementation groups were found to overlap. Also, most of the unique aut mutants accumulated precursor aminopeptidase I in the cytoplasm, while maintaining wild type kinetics and maturation of proteins targeted to the vacuole via the secretory pathway. The majority of the non-overlapping cvt mutants were found to be at least partially defective in autophagy. Some mutants in each group, however, appear to be only marginally affected in the other phenotype, implying that these pathways only partially overlap. We propose that import of aminopeptidase I into the vacuole shares a number of components required for bulk autophagocytosis, but is made specific, saturable, and constitutive by the presence of a receptor or other interacting protein(s).