ATPase and Multidrug Transport Activities of the Overexpressed Yeast ABC Protein Yor1p
The Saccharomyces cerevisiae genome encodes 15 fullsize ATP binding cassette transporters (ABC), of which PDR5, SNQ2, and YOR1 are known to be regulated by the transcription factors Pdr1p and Pdr3p (pleiotropic drug resistance). We have identified two new ABC transporter-encoding genes, PDR10 and PDR15, which were upregulated by the PDR1-3 mutation. These genes, as well as four other ABC transporter-encoding genes, were deleted in order to study the properties of Yor1p. The PDR1-3 gain-of-function mutant was then used to overproduce Yor1p up to 10% of the total plasma membrane proteins. Despite their different topologies, both Yor1p and Pdr5p mediated the ATP-dependent translocation of similar drugs and phospholipids across the yeast cell membrane. Both ABC transporters exhibit ATP hydrolysis in vitro, but Pdr5p ATPase activity is about 15 times higher than that of Yor1p, which may indicate mechanistic or regulatory differences between the two enzymes. The yeast YOR11 gene confers oligomycin resistance on overexpression in a 2-m plasmid (1). Its nucleotide sequence reveals an ORF of 1477 amino acids encoding an ABC protein highly homologous to mammalian transporters such as the multidrug resistance-conferring enzyme MRP (BLAST (see Ref. 2) sequence homology score: p ϭ e Ϫ228 ), the organic anion transporter cMOAT (p ϭ e Ϫ216 ), the sulfonylurea receptor (p ϭ e Ϫ164 ), and the cystic fibrosis transmembrane conductance regulator CFTR (p ϭ e Ϫ132 ). Yor1p is a "full-size" ABC transporter with the topology (TM-NBF) 2 (3, 4). It consists of two homologous halves, with each containing a putative ATP-binding domain (NBF) and a transmembrane domain of six membrane spans (TM). Cui et al. (5) showed that Yor1p confers resistance to a series of drugs including reveromycin A and suggested that Yor1p may be involved in the cellular efflux of organic anions including the fluorescent dye rhodamine B. They also showed that incubation with reveromycin A increases the YOR1 mRNA level. The transcription of YOR1 is controlled by the homologous pair of transcription factors Pdr1p/Pdr3p. The level of YOR1 transcription is decreased by the deletion of either PDR1 or PDR3 and increased in the presence of the gain-of-function PDR1 alleles (1).In this paper, we have investigated the transport activity of Yor1p. Building on previous studies, which indicated that the (TM-NBF) 2 -type Yor1p, together with the (NBF-TM) 2 -type Pdr5p and Snq2p ABC transporters, are overexpressed in the PDR1-3 mutant plasma membrane (6 -8), the PDR1-3 mutant has been used as a tool that enhances the Yor1p protein level. As another investigative tool, we constructed a set of isogenic strains, in the PDR1-3 mutant, with multiple deletions of homologous ABC genes since, in situations where two or more proteins located in the same subcellular compartment share a common substrate, a clear phenotype is only seen when all the corresponding genes are deleted, as illustrated by the work of Mahé et al. (9), who showed that Pdr5p and Snq2p have an overlapping transport ...
The exocyst is a multiprotein complex that plays an important role in secretory vesicle targeting and docking at the plasma membrane. Here we report the identification and characterization of a new component of the exocyst, Exo84p, in the yeast Saccharomyces cerevisiae. Yeast cells depleted of Exo84p cannot survive. These cells are defective in invertase secretion and accumulate vesicles similar to those in the late sec mutants. Exo84p co-immunoprecipitates with the exocyst components, and a portion of the Exo84p co-sediments with the exocyst complex in velocity gradients. The assembly of Exo84p into the exocyst complex requires two other subunits, Sec5p and Sec10p. Exo84p interacts with both Sec5p and Sec10p in a two-hybrid assay. Overexpression of Exo84p selectively suppresses the temperature sensitivity of a sec5 mutant. Exo84p specifically localizes to the bud tip or mother/daughter connection, sites of polarized secretion in the yeast S. cerevisiae. Exo84p is mislocalized in a sec5 mutant. These studies suggest that Exo84p is an essential protein that plays an important role in polarized secretion.Spatial regulation of secretion is fundamental to a wide range of biological processes such as epithelial cell polarity establishment and neuronal growth cone formation. The budding yeast Saccharomyces cerevisiae provides a particularly useful system to study the spatial regulation of secretion. S. cerevisiae cells reproduce by budding, a process that requires a sophisticated system for polarized delivery and docking of vesicles containing proteins and lipids for localized plasma membrane expansion. A set of SEC genes was isolated from yeast that are required for secretion (1). 10 of these genes (SEC1, are required at the post-Golgi stage of the secretory pathway. Sec4p and Sec2p, in concert with the yeast cytoskeleton, are thought to be important for polarized delivery of secretory vesicles to the plasma membrane (2). Sec3, -5, -6, -8, -10, and -15p and Exo70p interact with each other and form a multisubunit complex termed the exocyst (3, 4). Components of the complex are localized to the emerging bud tip and mother/daughter connection, regions of active exocytosis (3,5,21,22,25). The localization of Sec3p is independent of the secretory pathway and actin cytoskeleton, suggesting that it may provide a spatial landmark for vesicle docking at the plasma membrane (5). Another component of the exocyst, Sec15p, can associate with secretory vesicles and interact with GTP-bound Sec4p, thus providing a molecular connection between the vesicles and the specialized exocytic sites on the plasma membrane (6). The exocyst appears to play a key role in vesicle docking and may act to couple the Rab/GTPase to the membrane fusion machinery (6, 23).A complex homologous to the exocyst is present in mammalian cells. In Madin-Darby canine kidney cells, the exocyst proteins are localized to sites of new plasma membrane addition. Antibodies directed against Sec8p block basolateral secretion (7). In cultured hippocampal neurons, the com...
Background-Patients with sickle cell disease (SCD) often use emergency department services to obtain medical care. Limited information is available about emergency department use among patients with SCD.
The transcription regulators, PDR1 and PDR3, have been shown to activate the transcription of numerous genes involved in a wide range of functions, including resistance to physical and chemical stress, membrane transport, and organelle function in Saccharomyces cerevisiae. We report here that PDR1 and PDR3 also regulate the transcription of one or more undetermined genes that translocate endogenous and fluorescent-labeled (M-C6-NBD-PE) phosphatidylethanolamine across the plasma membrane. A combination of fluorescence microscopy, fluorometry, and quantitative analysis demonstrated that M-C6-NBD-PE can be translocated both inward and outward across the plasma membrane of yeast cells. Mutants, defective in the accumulation of M-C6-NBD-PE, were isolated by selectively photokilling normal cells that accumulated the fluorescent phospholipid. This led to the isolation of numerous trafficking in phosphatidylethanolamine (tpe) mutants that were defective in intracellular accumulation of M-C6-NBD-PE. Complementation cloning and linkage analysis led to the identification of the dominant mutation TPE1-1 as a new allele of PDR1 and the semidominant mutation tpe2-1 as a new allele of PDR3. The amount of endogenous phosphatidylethanolamine exposed to the outer leaflet of the plasma membrane was measured by covalent labeling with the impermeant amino reagent, trinitrobenzenesulfonic acid. The amount of outer leaflet phosphatidylethanolamine in both mutant strains increased four- to fivefold relative to the parent Tpe+ strain, indicating that the net inward flux of endogenous phosphatidylethanolamine as well as M-C6-NBD-PE was decreased. Targeted deletions of PDR1 in the new allele, PDR1-11, and PDR3 in the new allele, pdr3-11, resulted in normal M-C6-NBD-PE accumulation, confirming that PDR1-11 and pdr3-11 were gain-of-function mutations in PDR1 and PDR3, respectively. Both mutant alleles resulted in resistance to the drugs cycloheximide, oligomycin, and 4-nitroquinoline N-oxide (4-NQO). However, a previously identified drug-resistant allele, pdr3-2, accumulated normal amounts of M-C6-NBD-PE, indicating allele specificity for the loss of M-C6-NBD-PE accumulation. These data demonstrated that PDR1 and PDR3 regulate the net rate of M-C6-NBD-PE translocation (flip-flop) and the steady-state distribution of endogenous phosphatidylethanolamine across the plasma membrane.
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