A High Copy Suppressor Screen Reveals Genetic Interactions Between BET3 and a New Gene: Evidence for a Novel Complex in ER-to-Golgi Transport

A High Copy Suppressor Screen Reveals Genetic Interactions Between BET3 and a New Gene: Evidence for a Novel Complex in ER-to-Golgi Transport

Yu Jiang^a, Al Scarpa^a, Li Zhang^a, Shelly Stone^a, Ed Feliciano^a, and Susan Ferro-Novick^a
^a Howard Hughes Medical Institute and the Department of Cell Biology, Yale University School of Medicine, New Haven, Connecticut 06510

Corresponding author: Susan Ferro-Novick, Department of Cell Biology, Boyer Center for Molecular Medicine, Howard Hughes Medical Institute, 295 Congress Ave., Room 254B, New Haven, CT 06510.

Communicating editor: M. CARLSON

The BET3 gene in the yeast Saccharomyces cerevisiae encodesa 22-kD hydrophilic protein that is required for vesicular transportbetween the ER and Golgi complex. To gain insight into the roleof Bet3p, we screened for genes that suppress the growth defectof the temperature-sensitive bet3 mutant at 34°. This highcopy suppressor screen resulted in the isolation of a new gene,called BET5. BET5 encodes an essential 18-kD hydrophilic proteinthat in high copy allows growth of the bet3-1 mutant, but notother ER accumulating mutants. This strong and specific suppressionis consistent with the fact that Bet3p and Bet5p are membersof the same complex. Using PCR mutagenesis, we generated a temperature-sensitivemutation in BET5 (bet5-1) that blocks the transport of carboxypeptidaseY to the vacuole and prevents secretion of the yeast pheromone ${alpha}$ -factor at 37°. The precursor forms of these proteins thataccumulate in this mutant are indicative of a block in membranetraffic between the ER and Golgi apparatus. High copy suppressorsof the bet5-1 mutant include several genes whose products arerequired for ER-to-Golgi transport (BET1, SEC22, USO1 and DSS4)and the maintenance of the Golgi (ANP1). These findings supportthe hypothesis that Bet5p acts in conjunction with Bet3p tomediate a late stage in ER-to-Golgi transport. The identificationof mammalian homologues of Bet3p and Bet5p implies that theBet3p/Bet5p complex is highly conserved in evolution.

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