Mutation of the RGD sequence does not affect plasma membrane association and growth inhibitory effects of elevated IGFBP-2 in vivo

Vacuolar sequestration or cellular extrusion of glutathione-conjugated xenobiotics and catabolites by ATP-binding cassette (ABC) transporters is an important detoxification mechanism operating in many species. In this study, we show that the yeast ABC transporter Bpt1p, a paralogue of Ycf1p, acts as an ATP-dependent vacuolar pump for glutathione conjugates. Bpt1p, which is inhibited by vanadate and glibenclamide, accounts for one third of the total vacuolar transport of glutathione conjugates. Furthermore, immunoblot analyses show that Bpt1p levels are strongly elevated in early stationary phase, consistent with a function of Bpt1p in vacuolar detoxification.     

The Yeast ATP-binding Cassette (ABC) Transporter Ycf1p Enhances the Recruitment of the Soluble SNARE Vam7p to Vacuoles for Efficient Membrane Fusion

The Saccharomyces cerevisiae vacuole contains five ATP-binding cassette class C (ABCC) transporters, including Ycf1p, a family member that was originally characterized as a Cd²⁺ transporter. Ycf1p has also been found to physically interact with a wide array of proteins, including factors that regulate vacuole homeostasis. In this study, we examined the role of Ycf1p and other ABCC transporters in the regulation of vacuole homotypic fusion. We found that deletion of YCF1 attenuated in vitro vacuole fusion by up to 40% relative to wild-type vacuoles. Plasmid-expressed wild-type Ycf1p rescued the deletion phenotype; however, Ycf1p containing a mutation of the conserved Lys-669 to Met in the Walker A box of the first nucleotide-binding domain (Ycf1p^K669M) was unable to complement the fusion defect of ycf1Δ vacuoles. This indicates that the ATPase activity of Ycf1p is required for its function in regulating fusion. In addition, we found that deleting YCF1 caused a striking decrease in vacuolar levels of the soluble SNARE Vam7p, whereas total cellular levels were not altered. The attenuated fusion of ycf1Δ vacuoles was rescued by the addition of recombinant Vam7p to in vitro experiments. Thus, Ycf1p contributes in the recruitment of Vam7p to the vacuole for efficient membrane fusion.     

Mutational analysis of the Saccharomyces cerevisiae ATP-binding cassette transporter protein Ycf1p

Ycf1p is a member of the ATP-binding cassette transporter family of membrane proteins. Strong sequence similarity has been observed between Ycf1p, the cystic fibrosis transmembrane conductance regulator (CFTR) and multidrug resistance protein (MRP). In this work, we have examined the functional significance of several of the conserved amino acid residues and the genetic requirements for Ycf1p subcellular localization. Biochemical fractionation experiments have established that Ycf1p, expressed at single-copy gene levels, co-fractionates with the vacuolar membrane and that this co-fractionation is independent of vps15 , vps34 or end3 gene function. Several cystic fibrosis-associated alleles of the CFTR were introduced into Ycf1p and found to elicit defects analogous to those seen in the CFTR. An amino-terminal extension shared between Ycf1p and MRP, but absent from CFTR, was found to be required for Ycf1p function, but not its subcellular localization. Mutant forms of Ycf1p were also identified that exhibited enhanced biological function relative to the wild-type protein. These studies indicate that Ycf1p will provide a simple, genetically tractable model system for the study of the trafficking and function of ATP-binding cassette transporter proteins, such as the CFTR and MRP.     

Ycf1p-dependent Hg(II) detoxification in Saccharomyces cerevisiae.

In Saccharomyces cerevisiae, disruption of the YCF1 gene increases the sensitivity of cell growth to mercury. Transformation of the resulting ycf1 null mutant with a plasmid harbouring YCF1 under the control of the GAL promoter largely restores the wild-type resistance to the metal ion. The protective effect of Ycf1p against the toxicity of mercury is especially pronounced when yeast cells are grown in rich medium or in minimal medium supplemented with glutathione. Secretory vesicles from S. cerevisiae cells overproducing Ycf1p are shown to exhibit ATP-dependent transport of bis(glutathionato)mercury. Moreover, using beta-galactosidase as a reporter protein, a relationship between mercury addition and the activity of the YCF1 promoter can be shown. Altogether, these observations indicate a defence mechanism involving an induction of the expression of Ycf1p and transport by this protein of mercury-glutathione adducts into the vacuole. Finally, possible coparticipation in mercury tolerance of other ABC proteins sharing close homology with Ycf1p was investigated. Gene disruption experiments enable us to conclude that neither Bpt1p, Yor1p, Ybt1p nor YHL035p plays a major role in the detoxification of mercury.     

Negative regulation of the yeast ABC transporter Ycf1p by phosphorylation within its N-terminal extension

The yeast vacuolar membrane protein Ycf1p and its mammalian counterpart, MRP1, belong to the ABCC subfamily of ATP-binding cassette (ABC) transporters that rid cells of toxic endogenous and xenobiotic compounds. Like most members of the ABCC subfamily, Ycf1p contains an N-terminal extension in addition to its ABC "core" domain and transports substrates in the form of glutathione conjugates. Ycf1p is subject to complex regulation to ensure its optimal function. Previous studies showed that Ycf1p activity is stimulated by a guanine nucleotide exchange factor, Tus1p, and is positively regulated by phosphorylation in its ABC core domain at residues Ser-908 and Thr-911. Here we provide evidence that phosphorylation of Ser-251 in the Ycf1p N-terminal extension negatively regulates activity. Mutant Ycf1p-S251A exhibits increased resistance to cadmium in vivo and increased Ycf1p-dependent transport of [(3)H]estradiol-beta-17-glucuronide in vitro as compared with wild-type Ycf1p. Activity is restored to the wild-type level for Ycf1-S251E. To identify kinase(s) that negatively regulate Ycf1p function, we conducted an integrated membrane yeast two-hybrid (iMYTH) screen and identified two kinase genes, CKA1 and HAL5, deletion of which increases Ycf1p function. Genetic evidence suggests that Cka1p may regulate Ycf1p function through phosphorylation of Ser-251 either directly or indirectly. Overall, this study provides compelling evidence that negative, as well as positive, regulation of Ycf1p is mediated by phosphorylation.     

Requirement of the N-terminal extension for vacuolar trafficking and transport activity of yeast Ycf1p,an ATP-binding cassette transporter

Ycf1p is the prototypical member of the yeast multidrug resistance-associated protein (MRP) subfamily of ATP-binding cassette (ABC) transporters. Ycf1p resides in the vacuolar membrane and mediates glutathione-dependent transport processes that result in resistance to cadmium and other xenobiotics. A feature common to many MRP proteins that distinguishes them from other ABC transporters is the presence of a hydrophobic N-terminal extension (NTE), whose function is not clearly established. The NTE contains a membrane spanning domain (MSD0) with five transmembrane spans and a cytosolic linker region (L0). The goal of this study was to determine the functional significance of the NTE of Ycf1p by examining the localization and functional properties of Ycf1p partial molecules, expressed either singly or together. We show that MSD0 plays a critical role in the vacuolar membrane trafficking of Ycf1p, whereas L0 is dispensable for localization. On the other hand, L0 is required for transport function, as determined by monitoring cadmium resistance. We also examine an unusual aspect of Ycf1p biology, namely, the posttranslational proteolytic processing that occurs within a lumenal loop of Ycf1p. Processing is shown to be Pep4p dependent and thus serves as a convenient marker for proper vacuolar localization. The processed fragments associate with each other, suggesting that these natural cleavage products contribute together to Ycf1p function.     

A region within a lumenal loop of Saccharomyces cerevisiae Ycf1p directs proteolytic processing and substrate specificity

Ycf1p, a member of the yeast multidrug resistance-associated protein (MRP) subfamily of ATP-binding cassette proteins, is a vacuolar membrane transporter that confers resistance to a variety of toxic substances such as cadmium and arsenite. Ycf1p undergoes a PEP4-dependent processing event to yield N- and C-terminal cleavage products that remain associated with one another. In the present study, we sought to determine whether proteolytic cleavage is required for Ycf1p activity. We have identified a unique region within lumenal loop 6 of Ycf1p, designated the loop 6 insertion (L6_ins), which appears to be necessary and sufficient for proteolytic cleavage, since L6_ins can promote processing when moved to new locations in Ycf1p or into a related transporter, Bpt1p. Surprisingly, mutational results indicate that proteolytic processing is not essential for Ycf1p transport activity. Instead, the L6_ins appears to regulate substrate specificity of Ycf1p, since certain mutations in this region lower cellular cadmium resistance with a concomitant gain in arsenite resistance. Although some of these L6_ins mutations block processing, there is no correlation between processing and substrate specificity. The activity profiles of the Ycf1p L6_ins mutants are dramatically affected by the strain background in which they are expressed, raising the possibility that another cellular component may functionally impact Ycf1p activity. A candidate component may be a new full-length MRP-type transporter (NFT1), reported in the Saccharomyces Genome Database as two adjacent open reading frames, YKR103w and YKR104w, but which we show here is present in most Saccharomyces strains as a single open reading frame.     

The Rho1 GTPase acts together with a vacuolar glutathione S-conjugate transporter to protect yeast cells from oxidative stress

Maintenance of redox homeostasis is critical for the survival of all aerobic organisms. In the budding yeast Saccharomyces cerevisiae, as in other eukaryotes, reactive oxygen species (ROS) are generated during metabolism and upon exposure to environmental stresses. The abnormal production of ROS triggers defense mechanisms to avoid the deleterious consequence of ROS accumulation. Here, we show that the Rho1 GTPase is necessary to confer resistance to oxidants in budding yeast. Temperature-sensitive rho1 mutants (rho1(ts)) are hypersensitive to oxidants and exhibit high accumulation of ROS even at a semipermissive temperature. Rho1 associates with Ycf1, a vacuolar glutathione S-conjugate transporter, which is important for heavy metal detoxification in yeast. Rho1 and Ycf1 exhibit a two-hybrid interaction with each other and form a bimolecular fluorescent complex on the vacuolar membrane. A fluorescent-based complementation assay suggests that the GTP-bound Rho1 associates with Ycf1 and that their interaction is enhanced upon exposure to hydrogen peroxide. The rho1(ts) mutants also exhibit hypersensitivity to cadmium, while cells carrying a deletion of YCF1 or mutations in a component of the Pkc1-MAP kinase pathway exhibit little or minor sensitivity to oxidants. We thus propose that Rho1 protects yeast cells from oxidative stress by regulating multiple downstream targets including Ycf1. Since both Rho1 and Ycf1 belong to highly conserved families of proteins, similar mechanisms may exist in other eukaryotes.     

ABC Transporters in Saccharomyces cerevisiae and Their Interactors: New Technology Advances the Biology of the ABCC (MRP) Subfamily

Summary: Members of the ATP-binding cassette (ABC) transporter superfamily exist in bacteria, fungi, plants, and animals and play key roles in the efflux of xenobiotic compounds, physiological substrates, and toxic intracellular metabolites. Based on sequence relatedness, mammalian ABC proteins have been divided into seven subfamilies, ABC subfamily A (ABCA) to ABCG. This review focuses on recent advances in our understanding of ABC transporters in the model organism Saccharomyces cerevisiae. We propose a revised unified nomenclature for the six yeast ABC subfamilies to reflect the current mammalian designations ABCA to ABCG. In addition, we specifically review the well-studied yeast ABCC subfamily (formerly designated the MRP/CFTR subfamily), which includes six members (Ycf1p, Bpt1p, Ybt1p/Bat1p, Nft1p, Vmr1p, and Yor1p). We focus on Ycf1p, the best-characterized yeast ABCC transporter. Ycf1p is located in the vacuolar membrane in yeast and functions in a manner analogous to that of the human multidrug resistance-related protein (MRP1, also called ABCC1), mediating the transport of glutathione-conjugated toxic compounds. We review what is known about Ycf1p substrates, trafficking, processing, posttranslational modifications, regulation, and interactors. Finally, we discuss a powerful new yeast two-hybrid technology called integrated membrane yeast two-hybrid (iMYTH) technology, which was designed to identify interactors of membrane proteins. iMYTH technology has successfully identified novel interactors of Ycf1p and promises to be an invaluable tool in future efforts to comprehensively define the yeast ABC interactome.     

Functional domain analysis of the yeast ABC transporter Ycf1p by site-directed mutagenesis.

The yeast cadmium factor (Ycf1p) is a vacuolar protein involved in resistance to Cd(2+) and to exogenous glutathione S-conjugate precursors in yeast. It belongs to the superfamily of ATP binding cassette transporters, which includes the human cystic fibrosis transmembrane conductance regulator and the multidrug resistance-associated protein. To examine the functional significance of conserved amino acid residues in Ycf1p, we performed an extensive mutational analysis. Twenty-two single amino acid substitutions or deletions were generated by site-directed mutagenesis in the nucleotide binding domains, the proposed regulatory domain, and the fourth cytoplasmic loop. Mutants were analyzed phenotypically by measuring their ability to grow in the presence of Cd(2+). Expression and subcellular localization of the mutant proteins were examined by immunodetection in vacuolar membranes. For functional characterization of the Ycf1p variants, the kinetic parameters of glutathione S-conjugated leukotriene C(4) transport were measured. Our analysis shows that residues Ile(711), Leu(712), Phe(713), Glu(927), and Gly(1413) are essential for Ycf1p expression. Five other amino acids, Gly(663), Gly(756), Asp(777), Gly(1306), and Gly(1311), are critical for Ycf1p function, and two residues, Glu(709) and Asp(821), are unnecessary for Ycf1p biogenesis and function. We also identify several regulatory domain mutants in which Cd(2+) tolerance of the mutant strain and transport activity of the protein are dissociated.     

Ycf1-dependent cadmium detoxification by yeast requires phosphorylation of residues Ser908 and Thr911

Yeast cadmium factor (Ycf1), an ATP-binding cassette (ABC) protein of the multidrug resistance protein subfamily, is a vacuolar GS-conjugate transporter required for heavy metal and drug detoxification. There is evidence that phosphorylation may play a critical role in the function of ABC transporters from higher organisms. In this work, the possibility of Ycf1 phosphorylation was examined using site-directed mutagenesis. We demonstrate that Ser⁹⁰⁸ and Thr⁹¹¹, within the regulatory domain (R domain), are functionally important for Ycf1 transport activity and likely sites for phosphorylation. Mutation of these residues to alanine severely impaired the Ycf1-dependent cadmium detoxification capacity and transport activity, while replacement by acidic residues (mimicking phosphorylation) significantly suppressed the cadmium resistance and transport defects. Both in vitro treatment of Ycf1 with alkaline phosphatase and changes in the electrophoretic mobility of the S908A, T911A and double mutant S908A/T911A proteins supported the conclusion that Ycf1 is a phosphoprotein. The screening of the yeast kinome identified four protein kinases affecting cadmium detoxification, but none of them was involved directly in the phosphorylation of Ycf1. Our data strongly implicate Ycf1 phosphorylation as a key determinant in cadmium resistance in yeast, a significant finding given that very little is known about phosphorylation of ABC transporters in yeast.     

Identification of genes affecting selenite toxicity and resistance in Saccharomyces cerevisiae

Recent studies associating dietary selenium with reduced cancer susceptibility have aroused interest in this substance. In the millimolar range, selenite is toxic and slightly mutagenic for yeast. We show that selenite-treated yeast cells tend to arrest as large budded cells and that this arrest is abolished in a rad9 mutant that is significantly sensitive to selenite. Interestingly, a rev3 mutant affected in the error-prone repair pathway is also sensitive to selenite, whereas mutations in the other DNA repair pathways do not strongly affect resistance to selenite. We propose that selenite treatment leads to DNA damage inducing the RAD9-dependent cell cycle arrest. Selenite-induced DNA damage could be converted to mutations by the Rev3p-dependent lesion bypass system, thus allowing the cell cycle to progress. We have also investigated the selenite detoxification mechanisms and identified three genes involved in this process. In the present study, we show that lack of the cadmium glutathione-conjugate vacuolar pump Ycf1p or overexpression of the sulphite resistance membrane protein Ssu1p enhance the capacity of yeast cells to resist selenite treatment. Finally, we show that overexpression of the glutathione reductase Glr1p increases resistance to selenite, suggesting that selenite toxicity in yeast is closely linked to its oxidative capacity.     

Compartment-specific Synthesis of Phosphatidylethanolamine Is Required for Normal Heavy Metal Resistance

Control of lipid composition of membranes is crucial to ensure normal cellular functions. Saccharomyces cerevisiae has two different phosphatidylserine decarboxylase enzymes (Psd1 and Psd2) that catalyze formation of phosphatidylethanolamine. The mitochondrial Psd1 provides roughly 70% of the phosphatidylethanolamine (PE) biosynthesis in the cell with Psd2 carrying out the remainder. Here, we demonstrate that loss of Psd2 causes cells to acquire sensitivity to cadmium even though Psd1 remains intact. This cadmium sensitivity results from loss of normal activity of a vacuolar ATP-binding cassette transporter protein called Ycf1. Measurement of phospholipid levels indicates that loss of Psd2 causes a specific reduction in vacuolar membrane PE levels, whereas total PE levels are not significantly affected. The presence of a phosphatidylinositol transfer protein called Pdr17 is required for Psd2 function and normal cadmium tolerance. We demonstrate that Pdr17 and Psd2 form a complex in vivo that seems essential for maintenance of vacuolar PE levels. Finally, we refine the localization of Psd2 to the endosome arguing that this enzyme controls vacuolar membrane phospholipid content by regulating phospholipids in compartments that will eventually give rise to the vacuole. Disturbance of this regulation of intracellular phospholipid balance leads to selective loss of membrane protein function in the vacuole.     

The ABC transporter Pdr5p mediates the efflux of nonsteroidal ecdysone agonists in Saccharomyces cerevisiae.

We have previously shown that the synthetic nonsteroidal ecdysone agonist tebufenozide (RH-5992) is actively excluded by resistant cells of insects. To identify the transporter that could be involved in the efflux of RH-5992, the role of three ATP binding cassette transporters, Pdr5p, Snq2p and Ycf1p, has been studied using transporter-deletion mutants of yeast Saccharomyces cerevisiae. PDR5 (pleiotropic drug resistance 5) deletion mutants (Deltapdr5 and Deltapdr5Deltasnq2) retained significantly higher levels of 14C-radiolabeled RH-5992 within the cells when compared to wild-type strain or single deletion mutants of SNQ2 (Deltasnq2) and YCF1 (Deltaycf1). Introduction of an expression vector containing the PDR5 gene into the PDR5 single deletion mutant reversed the effect, resulting in the active exclusion of [14C]RH-5992 from these cells as efficiently as the wild-type cells. These results demonstrated that the ABC transporter Pdr5p but not Snq2p or Ycf1p was responsible for the active exclusion of [14C]RH-5992 in yeast. This exclusion was temperature-dependent and was blocked by the ATPase inhibitors oligomycin and vanadate, indicating that the efflux was an active process. The mutants with the PDR5 deletion can also selectively accumulate [14C]RH-0345 and [14C]RH-2485, but not [14C]RH-5849, indicating that these three compounds share the same transporter Pdr5p for efflux.     

Role of the yeast ABC transporter Yor1p in cadmium detoxification

Growth of yeast strains, either deleted for the vacuolar ABC transporter Ycf1 or deleted for the plasma membrane ABC transporter Yor1p or overexpressing Yor1p, were compared for their sensitivity to cadmium. On solid medium cell death (or growth inhibition) was observed at cadmium concentrations higher than 100 microM when yeasts were grown at 30 degrees C for 24 h. However, for all tested strains cell death (or growth inhibition) was already observed at 40 microM cadmium when incubated at 23 degrees C for 60 h. Thus cadmium is more toxic to yeast at 23 degrees C than at 30 degrees C. At 23 degrees C, the Deltayor1 strain grew more slowly than the wild-type strain and the double Deltayor1, Deltaycf1 deleted strain was much more sensitive to cadmium than each single Deltayor1 or Deltaycf1 deletant. Overexpression of Yor1p in a Deltaycf1 strain restores full growth. Cadmium uptake measurements show that Deltaycf1 yeast strains expressing or overexpressing Yor1p store less cadmium than the corresponding Deltaycf1, Deltayor1 strain. The strains expressing Yor1p display an energy-dependent efflux of cadmium estimated for the yeast overexpressing Yor1p to be about 0.02 nmol 109Cd/mg protein/min. Yeast cells loaded with radiolabeled glutathione and then with radioactive cadmium displayed a twice-higher efflux of glutathione than that of cadmium suggesting that Yor1p transports both compounds as a bis-glutathionato-cadmium complex. All together, these results suggest that in addition to being accumulated in the yeast vacuole by Ycf1p, cadmium is also effluxed out of the cell by Yor1p.     

Domain interactions in the yeast ATP binding cassette transporter Ycf1p: intragenic suppressor analysis of mutations in the nucleotide binding domains

The yeast cadmium factor (Ycf1p) is a vacuolar ATP binding cassette (ABC) transporter required for heavy metal and drug detoxification. Cluster analysis shows that Ycf1p is strongly related to the human multidrug-associated protein (MRP1) and cystic fibrosis transmembrane conductance regulator and therefore may serve as an excellent model for the study of eukaryotic ABC transporter structure and function. Identifying intramolecular interactions in these transporters may help to elucidate energy transfer mechanisms during transport. To identify regions in Ycf1p that may interact to couple ATPase activity to substrate binding and/or movement across the membrane, we sought intragenic suppressors of ycf1 mutations that affect highly conserved residues presumably involved in ATP binding and/or hydrolysis. Thirteen intragenic second-site suppressors were identified for the D777N mutation which affects the invariant Asp residue in the Walker B motif of the first nucleotide binding domain (NBD1). Two of the suppressor mutations (V543I and F565L) are located in the first transmembrane domain (TMD1), nine (A1003V, A1021T, A1021V, N1027D, Q1107R, G1207D, G1207S, S1212L, and W1225C) are found within TMD2, one (S674L) is in NBD1, and another one (R1415G) is in NBD2, indicating either physical proximity or functional interactions between NBD1 and the other three domains. The original D777N mutant protein exhibits a strong defect in the apparent affinity for ATP and V(max) of transport. The phenotypic characterization of the suppressor mutants shows that suppression does not result from restoring these alterations but rather from a change in substrate specificity. We discuss the possible involvement of Asp777 in coupling ATPase activity to substrate binding and/or transport across the membrane.