Down-Regulation of a Manganese Transporter in the Face of Metal Toxicity

The yeast Smf1p Nramp manganese transporter is posttranslationally regulated by environmental manganese. Smf1p is stabilized at the cell surface with manganese starvation, but is largely degraded in the vacuole with physiological manganese through a mechanism involving the Rsp5p adaptor complex Bsd2p/Tre1p/Tre2p. We now describe an additional level of Smf1p regulation that occurs with toxicity from manganese, but not other essential metals. This regulation is largely Smf1p-specific. As with physiological manganese, toxic manganese triggers vacuolar degradation of Smf1p by trafficking through the multivesicular body. However, regulation by toxic manganese does not involve Bsd2p/Tre1p/Tre2p. Toxic manganese triggers both endocytosis of cell surface Smf1p and vacuolar targeting of intracellular Smf1p through the exocytic pathway. Notably, the kinetics of vacuolar targeting for Smf1p are relatively slow with toxic manganese and require prolonged exposures to the metal. Down-regulation of Smf1p by toxic manganese does not require transport activity of Smf1p, whereas such transport activity is needed for Smf1p regulation by manganese starvation. Furthermore, the responses to manganese starvation and manganese toxicity involve separate cellular compartments. We provide evidence that manganese starvation is sensed within the lumen of the secretory pathway, whereas manganese toxicity is sensed within an extra-Golgi/cytosolic compartment of the cell.     

Transferrin receptor-like proteins control the degradation of a yeast metal transporter

Plasma membrane transporters are often downregulated by their substrates. The yeast manganese transporter Smf1 is subject to two levels of regulation: heavy metals induce its sequestration within the cell, and also its ubiquitination and degradation in the vacuole. Degradation requires Bsd2, a membrane protein with a PPxY motif that recruits the ubiquitin ligase Rsp5, and which has a role in the quality control of membrane proteins, that expose hydrophilic residues to the lipid bilayer. We show that degradation of Smf1 requires in addition one of a pair of related yeast proteins, Tre1 and Tre2, that also contain PPxY motifs. Tre1 can partially inhibit manganese uptake without Bsd2, but requires Bsd2 to induce Smf1 degradation. It has a relatively hydrophilic transmembrane domain and binds to Bsd2. We propose that the Tre proteins specifically link Smf1 to the Bsd2-dependent quality control system. Their luminal domains are related to the transferrin receptor, but these are dispensable for Smf1 regulation. Tre proteins and the transferrin receptors appear to have evolved independently from the same family of membrane-associated proteases.     

Yeast Mn2+ transporter, Smf1p, is regulated by ubiquitin-dependent vacuolar protein sorting

Conditional cdc1(Ts) mutants of S. cerevisiae arrest with a phenotype similar to that exhibited by Mn(2+)-depleted cells. Sequence similarity between Cdc1p and a class of Mn(2+)-dependent phosphoesterases, as well as the observation that conditional cdc1(Ts) growth can be ameliorated by Mn(2+) supplement, suggests that Cdc1p activity is sensitive to intracellular Mn(2+) levels. This article identifies several previously uncharacterized cdc1(Ts) suppressors as class E vps (vacuolar protein sorting) mutants and shows that these, as well as other vps mutants, accumulate high levels of intracellular Mn(2+). Yeast VPS genes play a role in delivery of membrane transporters to the vacuole for degradation, and we show that the vps mutants accumulate elevated levels of the high-affinity Mn(2+) transporter Smf1p. cdc1(Ts) conditional growth is also alleviated by mutations, including doa4 and ubc4, that compromise protein ubiquitination, and these ubiquitination defects are associated with Smf1p accumulation. Epistasis studies show that these suppressors require functional Smf1p to alleviate the cdc1(Ts) growth defect, whereas Smf1p is dispensable for cdc1(Ts) suppression by a mutation (cos16/per1) that does not influence intracellular Mn(2+) levels. Because Smf1p is ubiquitinated in vivo, we propose that Smf1p is targeted to the vacuole for degradation by ubiquitination-dependent protein sorting.     

The family of SMF metal ion transporters in yeast cells

Metal ions are vital for all organisms, and metal ion transporters play a crucial role in maintaining their homeostasis. The yeast (Saccharomyces cerevisiae) Smf transporters and their homologs in other organisms have a central role in the accumulation of metal ions and their distribution in different tissues and cellular organelles. In this work we generated null mutations in each individual SMF gene in yeast as well as in all combinations of the genes. Each null mutation exhibited sensitivity to metal ion chelators at different concentrations. The combination of null mutants DeltaSMF1 + DeltaSMF2 and the triple null mutant Delta3SMF failed to grow on medium buffered at pH 8 and 7.5, respectively. Addition of 5 microm copper or 25 microm manganese alleviated the growth arrest at the high pH or in the presence of the chelating agent. The transport of manganese was analyzed in the triple null mutant and in this mutant expressing each Smf protein. Although overexpression of Smf1p and Smf2p resulted in uptake that was higher than wild type cells, the expression of Smf3p gave no significant uptake above that of the triple mutant Delta3SMF. Western analysis with antibody against Smf3p indicated that this transporter does not reach the plasma membrane and may function at the Golgi or post-Golgi complexes. The iron uptake resulting from expression of Smf1p and Smf2p was analyzed in a mutant in which its iron transporters FET3 and FET4 were inactivated. Overexpression of Smf1p gave rise to a significant iron uptake that was sensitive to the sodium concentrations in the medium. We conclude that the Smf proteins play a major role in copper and manganese homeostasis and, under certain circumstances, Smf1p may function in iron transport into the cells.     

A novel role for Bsd2 in the resistance of yeast to adriamycin

In a search for undiscovered mechanisms of resistance to adriamycin, we screened a genomic library derived from Saccharomyces cerevisiae for genes related to adriamycin resistance. To our surprise, we found that overexpression of BSD2 rendered yeast cells resistant to adriamycin. Downregulation of the metal transporters Smf1 and Smf2 is the only activity of Bsd2 reported to date, and Bsd2 deficiency increases intracellular levels of Smf1 and Smf2. SMF2-disrupted cells exhibited significantly greater resistance to adriamycin, whereas the resistance of SMF1-disrupted cells was only slightly improved. The sensitivity of the SMF1- and SMF2-disrupted yeast cell line overexpressing BSD2 was almost the same as that of the BSD2-overexpressing parental yeast cell. Thus the overexpression of BSD2 and the disruption of SMF1 and SMF2 might be involved in the same mechanism that confers resistance to adriamycin. Although both SMF1- and SMF2-disrupted cells were very sensitive to EGTA, overexpression of BSD2 had little or no effect on sensitivity to EGTA. However, a partial decrease in the intracellular level of FLAG-Smf2 was observed by overexpression of BSD2. Thus, the resistance to adriamycin acquired by overexpression of BSD2 might be partially explained by down-regulation of Smf2, but in addition to Smf2, other as of yet unidentified targets of Bsd2 must also be responsible for the resistance.     

Site-directed mutagenesis investigation of coupling properties of metal ion transport by DCT1

DCT1 (NRAMP2, DMT1, slc11a2) is a member of the NRAMP family and functions as general metal ion transporter in mammals; defective DCT1 causes anemia. The driving force for metal ion transport is protonmotive force, where protons are transported in the same direction as metal ions. The stoichiometry between metal ion and proton varies under different conditions due to mechanistic proton slip. To better understand this phenomenon, we performed site-directed mutagenesis of DCT1 and analyzed the mutants by measurement of metal ion uptake activity and electrophysiology in Xenopus laevis oocytes. A single reciprocal mutation, I144F, between DCT1 and the homologous yeast transporter Smf1p located in putative transmembrane domain 2 abolished the metal ion transport activity of DCT1, significantly increased the slip currents, and generated sodium slip currents. A double mutation adding F227I in transmembrane domain 4 to I144F in transmembrane domain 2 restored the uptake activity of DCT1 and reduced the slip currents. These results demonstrate the importance of these regions in coupling of metal ions and protons as well as the possible proximity of I144 and F227 in the folded structure of DCT1.     

Site-directed mutagenesis investigation of coupling properties of metal ion transport by DCT1

DCT1 (NRAMP2, DMT1, slc11a2) is a member of the NRAMP family and functions as general metal ion transporter in mammals; defective DCT1 causes anemia. The driving force for metal ion transport is protonmotive force, where protons are transported in the same direction as metal ions. The stoichiometry between metal ion and proton varies under different conditions due to mechanistic proton slip. To better understand this phenomenon, we performed site-directed mutagenesis of DCT1 and analyzed the mutants by measurement of metal ion uptake activity and electrophysiology in Xenopus laevis oocytes. A single reciprocal mutation, I144F, between DCT1 and the homologous yeast transporter Smf1p located in putative transmembrane domain 2 abolished the metal ion transport activity of DCT1, significantly increased the slip currents, and generated sodium slip currents. A double mutation adding F227I in transmembrane domain 4 to I144F in transmembrane domain 2 restored the uptake activity of DCT1 and reduced the slip currents. These results demonstrate the importance of these regions in coupling of metal ions and protons as well as the possible proximity of I144 and F227 in the folded structure of DCT1.     

Degradation of the gluconeogenic enzyme fructose-1, 6-bisphosphatase is dependent on the vacuolar ATPase

The key gluconeogenic enzyme fructose-1,6-bisphosphatase (FBPase) is induced during glucose starvation. After the addition of glucose, inactivated FBPase is selectively targeted to Vid (vacuolar import and degradation) vesicles and then to the vacuole for degradation. To identify proteins involved in this pathway, we screened various libraries for mutants that failed to degrade FBPase. Via these approaches, subunits of the vacuolar- H+ -ATPase (V-ATPase) have been identified repeatedly. The V-ATPase has established roles in endocytosis, sorting of carboxypeptidase Y and homotypic vacuole fusion. Here, we show that mutants lacking Stv1p, Vph1p, and other subunits of the V-ATPase are defective for FBPase degradation. FBPase was detected in Vid vesicles. However, most FBPase was resistant to proteinase K digestion in the Deltavph1 or vma mutants, whereas the majority of FBPase was sensitive to proteinase K digestion in the Deltastv1 mutant. Therefore, STV1 and VPH1 have distinct functions in FBPase degradation. In cells lacking V0 genes, Vma2p and Vma5p were still detected on Vid vesicles and vacuoles, suggesting that the distribution of V1 proteins is independent of V0 genes. The V0 and V1 domains are assembled following a glucose shift and the assembly is not regulated by protein kinase A and RAV genes. Assembly of the V0 complex is necessary for FBPase trafficking, since mutants that block the assembly and transport of V0 out of the ER were defective in FBPase degradation.     

Degradation of the Gluconeogenic Enzyme Fructose-1,6-Bisphosphatase is Dependent on the Vacuolar ATPase

The key gluconeogenic enzyme fructose-1,6-bisphosphatase (FBPase) is induced during glucose starvation. After the addition of glucose, inactivated FBPase is selectively targeted to a novel type of Vid (vacuolar import and degradation) vesicle and then to the vacuole for degradation. To identify proteins involved in this pathway, we screened various libraries for mutants that failed to degrade FBPase. Via these approaches, subunits of the vacuolar H+ ATPase (V-ATPase) have been identified repeatedly. The VATPase has established roles in endocytosis, sorting of carboxypeptidase Y and homotypic vacuole fusion. Here, we show that Stv1p, Vph1p, and other subunits of the VATPase are required for FBPase degradation. VPH1 and V0 domain subunits such as Vma3p were required for both Vid vesicle and vacuole function, as determined by an in vitro fusion assay. However, STV1 was only required for the proper function of the Vid vesicles. We also show that the V1 domain participates in the Vid vesicle to vacuoletrafficking step, since most of the V1 subunits are necessary for Vid vesicle-vacuole fusionto occur. The V0 and V1 domains are assembled following a glucose shift and theassembly is independent of protein kinase A and RAV genes. Assembly of the V0 complexis necessary for FBPase trafficking, since mutants that block the assembly and transport ofV0 out of the ER were defective in FBPase degradation.     

The overlapping roles of manganese and Cu/Zn SOD in oxidative stress protection

In various organisms, high intracellular manganese provides protection against oxidative damage through unknown pathways. Herein we use a genetic approach in Saccharomyces cerevisiae to analyze factors that promote manganese as an antioxidant in cells lacking Cu/Zn superoxide dismutase (sod1 Delta). Unlike certain bacterial systems, oxygen resistance in yeast correlates with high intracellular manganese without a lowering of iron. This manganese for antioxidant protection is provided by the Nramp transporters Smf1p and Smf2p, with Smf1p playing a major role. In fact, loss of manganese transport by Smf1p together with loss of the Pmr1p manganese pump is lethal to sod1 Delta cells despite normal manganese SOD2 activity. Manganese-phosphate complexes are excellent superoxide dismutase mimics in vitro, yet through genetic disruption of phosphate transport and storage, we observed no requirement for phosphate in manganese suppression of oxidative damage. If anything, elevated phosphate correlated with profound oxidative stress in sod1 Delta mutants. The efficacy of manganese as an antioxidant was drastically reduced in cells that hyperaccumulate phosphate without effects on Mn SOD activity. Non-SOD manganese can provide a critical backup for Cu/Zn SOD1, but only under appropriate physiologic conditions.     

Multiple interactions drive adaptor-mediated recruitment of the ubiquitin ligase rsp5 to membrane proteins in vivo and in vitro

Recognition of membrane proteins by the Nedd4/Rsp5 ubiquitin ligase family is a critical step in their targeting to the multivesicular body pathway. Some substrates contain "PY" motifs (PPxY), which bind to WW domains in the ligase. Others lack PY motifs and instead rely on adaptors that recruit the ligase to them. To investigate the mechanism of adaptor-mediated ubiquitination, we have characterized the interactions between the adaptor Bsd2, the ubiquitin ligase Rsp5, and the membrane proteins Cps1, Tre1, and Smf1 from Saccharomyces cerevisiae. We have reconstituted adaptor-mediated modification of Cps1 and Tre1 in vitro, and we show that two PY motifs in Bsd2 and two WW domains (WW2 and WW3) in Rsp5 are crucial for this. The binding of a weak noncanonical DMAPSY motif in Bsd2 to WW3 is an absolute requirement for Bsd2 adaptor function. We show that sorting of the manganese transporter Smf1, which requires both Bsd2 and Tre1, depends upon two PY motifs in Bsd2 and one motif in Tre1 but only two WW domains in Rsp5. We suggest that sequential assembly of first a Bsd2/Rsp5 complex, then a Tre1/Bsd2/Rsp5 complex followed by a rearrangement of PY-WW interactions is required for the ubiquitination of Smf1.     

Frataxin depletion in yeast triggers up-regulation of iron transport systems before affecting iron-sulfur enzyme activities

The primary function of frataxin, a mitochondrial protein involved in iron homeostasis, remains controversial. Using a yeast model of conditional expression of the frataxin homologue YFH1, we analyzed the primary effects of YFH1 depletion. The main conclusion unambiguously points to the up-regulation of iron transport systems as a primary effect of YFH1 down-regulation. We observed that inactivation of aconitase, an iron-sulfur enzyme, occurs long after the iron uptake system has been activated. Decreased aconitase activity should be considered part of a group of secondary events promoted by iron overloading, which includes decreased superoxide dismutase activity and increased protein carbonyl formation. Impaired manganese uptake, which contributes to superoxide dismutase deficiency, has also been observed in YFH1-deficient cells. This low manganese content can be attributed to the down-regulation of the metal ion transporter Smf2. Low Smf2 levels were not observed in AFT1/YFH1 double mutants, indicating that high iron levels could be responsible for the Smf2 decline. In summary, the results presented here indicate that decreased iron-sulfur enzyme activities in YFH1-deficient cells are the consequence of the oxidative stress conditions suffered by these cells.     

The Saccharomyces cerevisiae high affinity phosphate transporter encoded by PHO84 also functions in manganese homeostasis

In the bakers' yeast Saccharomyces cerevisiae, high affinity manganese uptake and intracellular distribution involve two members of the Nramp family of genes, SMF1 and SMF2. In a search for other genes involved in manganese homeostasis, PHO84 was identified. The PHO84 gene encodes a high affinity inorganic phosphate transporter, and we find that its disruption results in a manganese-resistant phenotype. Resistance to zinc, cobalt, and copper ions was also demonstrated for pho84Delta yeast. When challenged with high concentrations of metals, pho84Delta yeast have reduced metal ion accumulation, suggesting that resistance is due to reduced uptake of metal ions. Pho84p accounted for virtually all the manganese accumulated under metal surplus conditions, demonstrating that this transporter is the major source of excess manganese accumulation. The manganese taken in via Pho84p is indeed biologically active and can not only cause toxicity but can also be incorporated into manganese-requiring enzymes. Pho84p is essential for activating manganese enzymes in smf2Delta mutants that rely on low affinity manganese transport systems. A role for Pho84p in manganese accumulation was also identified in a standard laboratory growth medium when high affinity manganese uptake is active. Under these conditions, cells lacking both Pho84p and the high affinity Smf1p transporter accumulated low levels of manganese, although there was no major effect on activity of manganese-requiring enzymes. We conclude that Pho84p plays a role in manganese homeostasis predominantly under manganese surplus conditions and appears to be functioning as a low affinity metal transporter.     

Starvation-induced degradation of yeast hexose transporter Hxt7p is dependent on endocytosis, autophagy and the terminal sequences of the permease

The yeast high-affinity glucose transporters Hxt6p and Hxt7p are rapidly degraded during nitrogen starvation in the presence of high concentrations of fermentable carbon sources. Our results suggest that degradation is mainly due to the stimulation of general protein turnover and not caused by a mechanism specifically triggered by glucose. Analysis of Hxt6p/7p stability and cellular distribution in end4, aut2 and apg1 mutants indicates that Hxt7p is internalized by endocytosis, and autophagy is involved in the final delivery of Hxt7p to the vacuole for proteolytic degradation. Internalization and degradation of Hxt7p were blocked after truncation of its N-terminal hydrophilic domain. Nevertheless, this fully functional and stabilized hexose transporter could not maintain fermentation capacity of the yeast cells under starvation conditions, indicating a regulatory constraint on glucose uptake.     

Functional analysis of a relA/spoT gene homolog from Streptococcus equisimilis.

We examined the functional attributes of a gene encountered by sequencing the streptokinase gene region of Streptococcus equisimilis H46A. This gene, originally called rel, here termed relS. equisimilis, is homologous to two related Escherichia coli genes, spoT and relA, that function in the metabolism of guanosine 5',3'-polyphosphates [(p)ppGpp]. Studies with a variety of E. coli mutants led us to deduce that the highly expressed rel S. equisimilis gene encodes a strong (p)ppGppase and a weaker (p)ppGpp synthetic activity, much like the spoT gene, with a net effect favoring degradation and no complementation of the absence of the relA gene. We verified that the Rel S. equisimilis protein, purified from an E. coli relA spoT double mutant, catalyzed a manganese-activated (p)ppGpp 3'-pyrophosphohydrolase reaction similar to that of the SpoT enzyme. This Rel S. equisimilis protein preparation also weakly catalyzed a ribosome-independent synthesis of (p)ppGpp by an ATP to GTP 3'-pyrophosphoryltransferase reaction when degradation was restricted by the absence of manganese ions. An analogous activity has been deduced for the SpoT protein from genetic evidence. In addition, the Rel S. equisimilis protein displays immunological cross-reactivity with polyclonal antibodies specific for SpoT but not for RelA. Despite assignment of rel S. equisimilis gene function in E. coli as being similar to that of the native spoT gene, disruptions of rel S. equisimilis in S. equisimilis abolish the parental (p)ppGpp accumulation response to amino acid starvation in a manner expected for relA mutants rather than spoT mutants.     

The NRAMP family of metal-ion transporters

The family of NRAMP metal ion transporters functions in diverse organisms from bacteria to human. NRAMP1 functions in metal transport across the phagosomal membrane of macrophages, and defective NRAMP1 causes sensitivity to several intracellular pathogens. DCT1 (NRAMP2) transport metal ions at the plasma membrane of cells of both the duodenum and in peripheral tissues, and defective DCT1 cause anemia. The driving force for the metal-ion transport is proton gradient (protonmotive force). In DCT1 the stoichiometry between metal ion and proton varied at different conditions due to a mechanistic proton slip. Though the metal ion transport by Smf1p, the yeast homolog of DCT1, is also a protonmotive force, a slippage of sodium ions was observed. The mechanism of the above phenomena could be explained by a combination between transporter and channel mechanisms.     

Yol082p, a novel CVT protein involved in the selective targeting of aminopeptidase I to the yeast vacuole

The yeast vacuolar enzyme aminopeptidase I (API) is synthesized in the cytoplasm as a precursor (pAPI). Upon its assembly into dodecamers, pAPI is wrapped by double-membrane saccular structures for its further transport within vesicles that fuse with the vacuolar membrane and release their content in the vacuolar lumen. Targeting of API to the vacuole occurs by two alternative transport routes, the cvt and the autophagy pathways, which although mechanistically similar specifically operate under vegetative growth or nitrogen starvation conditions, respectively. We have studied the role of Yol082p, a protein identified by its ability to interact with API, in the transport of its precursor to the vacuole. We show that Yol082p interacts with mature API, an interaction that is strengthened by the amino extension of the API protein. Yol082p is required for targeting of pAPI to the vacuole, both under growing and short term nitrogen starvation conditions. Absence of Yol082p does not impede the assembly of pAPI into dodecamers, but precludes the enclosure of pAPI within transport vesicles. Microscopy studies show that during vegetative growth Yol082p is distributed between a cytoplasmic pool and a variable number of 0.13--0.27-microm round, mobile structures, which are no longer observed under conditions of nitrogen starvation, and become larger in cells expressing the inactive Yol082 Delta C32p, or lacking Apg12p. In contrast to the autophagy mutants involved in API transport, a Delta yol082 strain does not lose viability under nitrogen starvation conditions, indicating normal function of the autophagy pathway. The data are consistent with a role of Yol082p in an early step of the API transport, after its assembly into dodecamers. Because Yol082p fulfills the functional requisites that define the CVT proteins, we propose to name it Cvt19.     

AUT3, a serine/threonine kinase gene, is essential for autophagocytosis in Saccharomyces cerevisiae.

Autophagocytosis is a starvation-induced process, carrying proteins destined for degradation to the lysosome. In the yeast Saccharomyces cerevisiae, the autophagic process is visualized by the appearance of autophagic vesicles in the vacuoles of proteinase yscB-deficient strains during starvation. aut3-1 mutant cells which exhibit a block in the autophagic process have been isolated previously. By using the drastically reduced sporulation frequency of homozygous aut3-1 diploid cells, the AUT3 gene was cloned by complementation. The Aut3 protein consists of 897 amino acids. The amino-terminal part of the protein shows significant homologies to serine/threonine kinases. aut3 null mutant cells are fully viable on rich media but show a reduced survival rate upon starvation. They are unable to accumulate autophagic vesicles in the vacuole during starvation. Starvation-induced vacuolar protein breakdown is almost completely impaired in aut3-deficient cells. Vacuolar morphology and acidification are not influenced in aut3-deficient cells. Also, secretion of invertase, endocytic uptake of Lucifer Yellow, and vacuolar protein sorting appear wild type like in aut3-deficient cells, suggesting autophagocytosis as a novel route for the transport of proteins from the cytosol to the vacuole. By using a fusion of Aut3p with green-fluorescent protein, Aut3p was localized to the cytosol.     

Autophagy and the cvt pathway both depend on AUT9

In growing cells of the yeast Saccharomyces cerevisiae, proaminopeptidase I reaches the vacuole via the selective cytoplasm-to-vacuole targeting (cvt) pathway. During nutrient limitation, autophagy is also responsible for the transport of proaminopeptidase I. These two nonclassical protein transport pathways to the vacuole are distinct in their characteristics but in large part use identical components. We expanded our initial screen for aut(-) mutants and isolated aut9-1 cells, which show a defect in both pathways, the vacuolar targeting of proaminopeptidase I and autophagy. By complementation of the sporulation defect of homocygous diploid aut9-1 mutant cells with a genomic library, in this study we identified and characterized the AUT9 gene, which is allelic with CVT7. aut9-deficient cells have no obvious defects in growth on rich media, vacuolar biogenesis, and acidification, but like other mutant cells with a defect in autophagy, they exhibit a reduced survival rate and reduced total protein turnover during starvation. Aut9p is the first putative integral membrane protein essential for autophagy. A biologically active green fluorescent protein-Aut9 fusion protein was visualized at punctate structures in the cytosol of growing cells.