Clathrin and two components of the COPII complex, Sec23p and Sec24p, could be involved in endocytosis of the Saccharomyces cerevisiae maltose transporter

The Saccharomyces cerevisiae maltose transporter is a 12-transmembrane segment protein that under certain physiological conditions is degraded in the vacuole after internalization by endocytosis. Previous studies showed that endocytosis of this protein is dependent on the actin network, is independent of microtubules, and requires the binding of ubiquitin. In this work, we attempted to determine which coat proteins are involved in this endocytosis. Using mutants defective in the heavy chain of clathrin and in several subunits of the COPI and the COPII complexes, we found that clathrin, as well as two cytosolic subunits of COPII, Sec23p and Sec24p, could be involved in internalization of the yeast maltose transporter. The results also indicate that endocytosis of the maltose transporter and of the alpha-factor receptor could have different requirements.     

Endocytosis and vacuolar degradation of the plasma membrane-localized Pdr5 ATP-binding cassette multidrug transporter in Saccharomyces cerevisiae.

Multidrug resistance (MDR) to different cytotoxic compounds in the yeast Saccharomyces cerevisiae can arise from overexpression of the Pdr5 (Sts1, Ydr1, or Lem1) ATP-binding cassette (ABC) multidrug transporter. We have raised polyclonal antibodies recognizing the yeast Pdr5 ABC transporter to study its biogenesis and to analyze the molecular mechanisms underlying MDR development. Subcellular fractionation and indirect immunofluorescence experiments showed that Pdr5 is localized in the plasma membrane. In addition, pulse-chase radiolabeling of cells and immunoprecipitation indicated that Pdr5 is a short-lived membrane protein with a half-life of about 60 to 90 min. A dramatic metabolic stabilization of Pdr5 was observed in delta pep4 mutant cells defective in vacuolar proteinases, and indirect immunofluorescence showed that Pdr5 accumulates in vacuoles of stationary-phase delta pep4 mutant cells, demonstrating that Pdr5 turnover requires vacuolar proteolysis. However, Pdr5 turnover does not require a functional proteasome, since the half-life of Pdr5 was unaffected in either pre1-1 or pre1-1 pre2-1 mutants defective in the multicatalytic cytoplasmic proteasome that is essential for cytoplasmic protein degradation. Immunofluorescence analysis revealed that vacuolar delivery of Pdr5 is blocked in conditional end4 endocytosis mutants at the restrictive temperature, showing that endocytosis delivers Pdr5 from the plasma membrane to the vacuole.     

Catabolite inactivation of the galactose transporter in the yeast Saccharomyces cerevisiae: ubiquitination, endocytosis, and degradation in the vacuole.

When Saccharomyces cerevisiae cells growing on galactose are transferred onto glucose medium containing cycloheximide, an inhibitor of protein synthesis, a rapid reduction of Gal2p-mediated galactose uptake is observed. We show that glucose-induced inactivation of Gal2p is due to its degradation. Stabilization of Gal2p in pra1 mutant cells devoid of vacuolar proteinase activity is observed. Subcellular fractionation and indirect immunofluorescence showed that the Gal2 transporter accumulates in the vacuole of the mutant cells, directly demonstrating that its degradation requires vacuolar proteolysis. In contrast, Gal2p degradation is proteasome independent since its half-life is unaffected in pre1-1 pre2-2, cim3-1, and cim5-1 mutants defective in several subunits of the protease complex. In addition, vacuolar delivery of Gal2p was shown to be blocked in conditional end3 and end4 mutants at the nonpermissive temperature, indicating that delivery of Gal2p to the vacuole occurs via the endocytic pathway. Taken together, the results presented here demonstrate that glucose-induced proteolysis of Gal2p is dependent on endocytosis and vacuolar proteolysis and is independent of the functional proteasome. Moreover, we show that Gal2p is ubiquitinated under conditions of glucose-induced inactivation.     

Expression and degradation of the cystic fibrosis transmembrane conductance regulator in Saccharomyces cerevisiae

Many cystic fibrosis disease-associated mutations cause a defect in the biosynthetic processing and trafficking of the cystic fibrosis transmembrane conductance regulator (CFTR) protein. Yeast mutants, defective at various steps of the secretory pathway, have been used to dissect the mechanisms of biosynthetic processing and intracellular transport of several proteins. To exploit these yeast mutants, we have employed an expression system in which the CFTR gene is driven by the promoter of a structurally related yeast ABC protein, Pdr5p. Pulse-chase experiments revealed a turnover rate similar to that of nascent CFTR in mammalian cells. Immunofluorescence microscopy showed that most CFTR colocalized with the endoplasmic reticulum (ER) marker protein Kar2p and not with a vacuolar marker. Degradation was not influenced by the vacuolar protease mutants Pep4p and Prb1p but was sensitive to the proteasome inhibitor lactacystin beta-lactone. Blocking ER-to-Golgi transit with the sec18-1 mutant had little influence on turnover indicating that it occurred primarily in the ER compartment. Degradation was slowed in cells deficient in the ER degradation protein Der3p as well as the ubiquitin-conjugating enzymes Ubc6p and Ubc7p. Finally a mutation (sec61-2) in the translocon protein Sec61p that prevents retrotranslocation across the ER membrane also blocked degradation. These results indicate that whereas approximately 75% of nascent wild-type CFTR is degraded at the ER of mammalian cells virtually all of the protein meets this fate on heterologous expression in Saccharomyces cerevisiae.     

Distinct domains within yeast Sec61p involved in post-translational translocation and protein dislocation

The translocation of secretory polypeptides into and across the membrane of the endoplasmic reticulum (ER) occurs at the translocon, a pore-forming structure that orchestrates the transport and maturation of polypeptides at the ER membrane. Recent data also suggest that misfolded or unassembled polypeptides exit the ER via the translocon for degradation by the cytosolic ubiquitin/proteasome pathway. Sec61p is a highly conserved multispanning membrane protein that constitutes a core component of the translocon. We have found that the essential function of the Saccharomyces cerevisiae Sec61p is retained upon deletion of either of two internal regions that include transmembrane domains 2 and 3, respectively. However, a deletion mutation encompassing both of these domains was found to be nonfunctional. Characterization of yeast mutants expressing the viable deletion alleles of Sec61p has revealed defects in post-translational translocation. In addition, the transmembrane domain 3 deletion mutant is induced for the unfolded protein response and is defective in the dislocation of a misfolded ER protein. These data demonstrate that the various activities of Sec61p can be functionally dissected. In particular, the transmembrane domain 2 region plays a role in post-translational translocation that is required neither for cotranslational translocation nor for protein dislocation.     

A pre-immediate-early role for tegument ICP0 in the proteasome-dependent entry of herpes simplex virus

Herpes simplex virus (HSV) entry requires host cell 26S proteasomal degradation activity at a postpenetration step. When expressed in the infected cell, the HSV immediate-early protein ICP0 has E3 ubiquitin ligase activity and interacts with the proteasome. The cell is first exposed to ICP0 during viral entry, since ICP0 is a component of the inner tegument layer of the virion. The function of tegument ICP0 is unknown. Deletion of ICP0 or mutations in the N-terminal RING finger domain of ICP0 results in the absence of ICP0 from the tegument. We show here that these mutations negatively influenced the targeting of incoming capsids to the nucleus. Inhibitors of the chymotrypsin-like activity of the proteasome the blocked entry of virions containing tegument ICP0, including ICP0 mutants that are defective in USP7 binding. However, ICP0-deficient virions were not blocked by proteasomal inhibitors and entered cells via a proteasome-independent mechanism. ICP0 appeared to play a postpenetration role in cells that supported either endocytosis or nonendosomal entry pathways for HSV. The results suggest that ICP0 mutant virions are defective upstream of viral gene expression at a pre-immediate-early step in infection. We propose that proteasome-mediated degradation of a virion or host protein is regulated by ICP0 to allow efficient delivery of entering HSV capsids to the nuclear periphery.     

Degradation of subunits of the Sec61p complex, an integral component of the ER membrane, by the ubiquitin-proteasome pathway.

We have investigated the degradation of subunits of the trimeric Sec61p complex, a key component of the protein translocation apparatus of the ER membrane. A mutant form of Sec6lp and one of the two associated proteins (Sss1p) are selectively degraded, while the third constituent of the complex (Sbh1p) is stable. Our results demonstrate that the proteolysis of the multispanning membrane protein Sec61p is mediated by the ubiquitin-proteasome pathway, since it requires polyubiquitination, the presence of a membrane-bound (Ubc6) and a soluble (Ubc7) ubiquitin-conjugating enzyme and a functional proteasome. The process is proposed to be specific for unassembled Sec61p and Sss1p. Thus, our results suggest that one pathway of ER degradation of abnormal or unassembled membrane proteins is initiated at the cytoplasmic side of the ER.     

Role for the Ubiquitin-Proteasome System in the Vacuolar Degradation of Ste6p, the a-Factor Transporter in Saccharomyces cerevisiae

Ste6p, the a-factor transporter in Saccharomyces cerevisiae, is a multispanning membrane protein with 12 transmembrane spans and two cytosolic ATP binding domains. Ste6p belongs to the ATP binding cassette (ABC) superfamily and provides an excellent model for examining the intracellular trafficking of a complex polytopic membrane protein in yeast. Previous studies have shown that Ste6p undergoes constitutive endocytosis from the plasma membrane, followed by delivery to the vacuole, where it is degraded in a Pep4p-dependent manner, even though only a small portion of Ste6p is exposed to the vacuolar lumen where the Pep4p-dependent proteases reside. Ste6p is known to be ubiquitinated, a modification that may facilitate its endocytosis. In the present study, we further investigated the intracellular trafficking of Ste6p, focusing on the role of the ubiquitin-proteasome machinery in the metabolic degradation of Ste6p. We demonstrate by pulse-chase analysis that the degradation of Ste6p is impaired in mutants that exhibit defects in the activity of the proteasome (doa4 and pre1,2). Likewise, by immunofluorescence, we observe that Ste6p accumulates in the vacuole in the doa4 mutant, as it does in the vacuolar protease-deficient pep4 mutant. One model consistent with our results is that the degradation of Ste6p, the bulk of which is exposed to the cytosol, requires the activity of both the cytosolic proteasomal degradative machinery and the vacuolar lumenal proteases, acting in a synergistic fashion. Alternatively, we discuss a second model whereby the ubiquitin-proteasome system may indirectly influence the Pep4p-dependent vacuolar degradation of Ste6p. This study establishes that Ste6p is distinctive in that two independent degradative systems (the vacuolar Pep4p-dependent proteases and the cytosolic proteasome) are both involved, either directly or indirectly, in the metabolic degradation of a single substrate.     

Catabolite inactivation of the maltose transporter in nitrogen-starved yeast could be due to the stimulation of general protein turnover

Addition of glucose to Saccharomyces cerevisiae inactivates the maltose transporter. The general consensus is that this inactivation, called catabolite inactivation, is one of the control mechanisms developed by this organism to use glucose preferentially whenever it is available. Using nitrogen-starved cells (resting cells), it has been shown that glucose triggers endocytosis and degradation of the transporter in the vacuole. We now show that maltose itself triggers inactivation and degradation of its own transporter as efficiently as glucose. This fact, and the observation that glucose inactivates a variety of plasma membrane proteins including glucose transporters themselves, suggests that catabolite inactivation of the maltose transporter in nitrogen-starved cells is not a control mechanism specifically directed to ensure a preferential use of glucose. It is proposed that, in this metabolic condition, inactivation of the maltose transporter might be due to the stimulation of the general protein turnover that follows nitrogen starvation.     

Role of the proteasome in membrane extraction of a short-lived ER-transmembrane protein.

Selective degradation of proteins at the endoplasmic reticulum (ER-associated degradation) is thought to proceed largely via the cytosolic ubiquitin-proteasome pathway. Recent data have indicated that the dislocation of short-lived integral-membrane proteins to the cytosolic proteolytic system may require components of the Sec61 translocon. Here we show that the proteasome itself can participate in the extraction of an ER-membrane protein from the lipid bilayer. In yeast mutants expressing functionally attenuated proteasomes, degradation of a short-lived doubly membrane-spanning protein proceeds rapidly through the N-terminal cytosolic domain of the substrate, but slows down considerably when continued degradation of the molecule requires membrane extraction. Thus, proteasomes engaged in ER degradation can directly process transmembrane proteins through a mechanism in which the dislocation of the substrate and its proteolysis are coupled. We therefore propose that the retrograde transport of short-lived substrates may be driven through the activity of the proteasome.     

Two distinct proteolytic systems responsible for glucose-induced degradation of fructose-1,6-bisphosphatase and the Gal2p transporter in the yeast Saccharomyces cerevisiae share the same protein components of the glucose signaling pathway.

Addition of glucose to Saccharomyces cerevisiae inactivates the galactose transporter Gal2p and fructose-1,6-bisphosphatase (FBPase) by a mechanism called glucose- or catabolite-induced inactivation, which ultimately results in a degradation of both proteins. It is well established, however, that glucose induces internalization of Gal2p into the endocytotic pathway and its subsequent proteolysis in the vacuole, whereas FBPase is targeted to the 26 S proteasome for proteolysis under similar inactivation conditions. Here we report that two distinct proteolytic systems responsible for specific degradation of two conditionally short-lived protein targets, Gal2p and FBPase, utilize most (if not all) protein components of the same glucose sensing (signaling) pathway. Indeed, initiation of Gal2p and FBPase proteolysis appears to require rapid transport of those substrates of the Hxt transporters that are at least partially metabolized by hexokinase Hxk2p. Also, maltose transported via the maltose-specific transporter(s) generates an appropriate signal that culminates in the degradation of both proteins. In addition, Grr1p and Reg1p were found to play a role in transduction of the glucose signal for glucose-induced proteolysis of Gal2p and FBPase. Thus, one signaling pathway initiates two different proteolytic mechanisms of catabolite degradation, proteasomal proteolysis and endocytosis followed by lysosomal proteolysis.     

Moderate concentrations of ethanol inhibit endocytosis of the yeast maltose transporter.

The maltose transporter in Saccharomyces cerevisiae is degraded in the vacuole after internalization by endocytosis upon nitrogen starvation in the presence of a fermentable substrate. This degradation, known as catabolite inactivation, is inhibited by the presence of moderate concentrations (2 to 6%, vol/vol) of ethanol. We have investigated the mechanism of this inactivation and have found that it is due to the inhibition of the internalization of the transporter by endocytosis. The results also indicate that this inhibition is due to alterations produced by ethanol in the organization of the plasma membrane which also affects to endocytosis of other plasma membrane proteins. Apparently, endocytosis is particularly sensitive to these alterations compared with other processes occurring at the plasma membrane.     

Sec61p mediates export of a misfolded secretory protein from the endoplasmic reticulum to the cytosol for degradation.

Degradation of misfolded secretory proteins has long been assumed to occur in the lumen of the endoplasmic reticulum (ER). Recent evidence, however, suggests that such proteins are instead degraded by proteasomes in the cytosol, although it remains unclear how the proteins are transported out of the ER. Here we provide the first genetic evidence that Sec61p, the pore-forming subunit of the protein translocation channel in the ER membrane, is directly involved in the export of misfolded secretory proteins. We describe two novel mutants in yeast Sec61p that are cold-sensitive for import into the ER in both intact yeast cells and a cell-free system. Microsomes derived from these mutants are defective in exporting misfolded secretory proteins. These proteins become trapped in the ER and are associated with Sec61p. We conclude that misfolded secretory proteins are exported for degradation from the ER to the cytosol via channels formed by Sec61p.     

Functional analysis of Rpn6p, a lid component of the 26 S proteasome, using temperature-sensitive rpn6 mutants of the yeast Saccharomyces cerevisiae

Rpn6p is a component of the lid of the 26 S proteasome. We isolated and analyzed two temperature-sensitive rpn6 mutants in the yeast, Saccharomyces cerevisiae. Both mutants showed defects in protein degradation in vivo. However, the affinity-purified 26 S proteasome of the rpn6 mutants grown at the permissive temperature degraded polyubiquitinated Sic1p efficiently, even at a higher temperature. Interestingly, their enzyme activity was even higher at a higher temperature, indicating that once made mutant proteasomes are stable and have little defect in the proteolytic function. These results suggest that the deficiency in protein degradation observed in vivo is rather due to a defect in the assembly of a holoenzyme at the restrictive temperature. Indeed, both rpn6 mutants grown at the restrictive temperature were defective in assembling the 26 S proteasome. A striking feature of the rpn6 mutants at the restrictive temperature was that there appeared a protein complex composed of only four of the nine lid components, Rpn5p, Rpn8p, Rpn9p, and Rpn11p. Altogether, we conclude that Rpn6p is essential for the integrity/assembly of the lid in the sense that it is necessary for the incorporation of Rpn3p, Rpn7p, Rpn12p, and Sem1p (Rpn15p) into the lid, thereby playing an essential role in the proper function of the 26 S proteasome.     

Regulation of copper-dependent endocytosis and vacuolar degradation of the yeast copper transporter, Ctr1p, by the Rsp5 ubiquitin ligase

The Saccharomyces cerevisiae high-affinity copper transporter, Ctr1p, mediates cellular uptake of Cu(I). We report that when copper (50 microm CuSO(4)) is added to the growth medium of copper-starved cells, Ctr1p is rapidly internalized by endocytosis, delivered to the lumen of the lysosome-like vacuole and slowly degraded by vacuolar proteases. Through analysis of the trafficking and degradation of Ctr1p mutants, two lysine residues in the C-terminal cytoplasmic tail of Ctr1p, Lys340 and Lys345, were found to be critical for copper-dependent endocytosis and degradation. In response to copper addition, Ctr1p was found to be ubiquitylated and a mutation in the Rsp5 ubiquitin ligase largely abolished ubiquitylation, endocytosis and degradation. In a strain lacking the Rsp5p accessory factors Bul1p and Bul2p, endocytosis and degradation of Ctr1p-green fluorescent protein were substantially diminished. Surprisingly, a Ctr1p mutant that lacks Lys340 and Lys345 was still ubiquitylated in a copper-dependent manner, indicating that ubiquitylation of Ctr1p on other sites is insufficient to drive copper-dependent endocytosis and degradation. This study demonstrates that copper regulates turnover of Ctr1p by stimulating Rsp5p-dependent endocytosis and degradation of Ctr1p in the vacuole.     

A novel fluorescence-activated cell sorter-based screen for yeast endocytosis mutants identifies a yeast homologue of mammalian eps15

A complete understanding of the molecular mechanisms of endocytosis requires the discovery and characterization of the protein machinery that mediates this aspect of membrane trafficking. A novel genetic screen was used to identify yeast mutants defective in internalization of bulk lipid. The fluorescent lipophilic styryl dye FM4-64 was used in conjunction with FACS to enrich for yeast mutants that exhibit internalization defects. Detailed characterization of two of these mutants, dim1-1 and dim2-1, revealed defects in the endocytic pathway. Like other yeast endocytosis mutants, the temperature-sensitive dim mutant were unable to endocytose FM4-64 or radiolabeled alpha-factor as efficiently as wild-type cells. In addition, double mutants with either dim1-delta or dim2-1 and the endocytosis mutants end4-1 or act1-1 displayed synthetic growth defects, indicating that the DIM gene products function in a common or parallel endocytic pathway. Complementation cloning of the DIM genes revealed identity of DIM1 to SHE4 and DIM2 to PAN1. Pan1p shares homology with the mammalian clathrin adaptor-associated protein, eps15. Both proteins contain multiple EH (eps15 homology) domains, a motif proposed to mediate protein-protein interactions. Phalloidin labeling of filamentous actin revealed profound defects in the actin cytoskeleton in both dim mutants. EM analysis revealed that the dim mutants accumulate vesicles and tubulo-vesicular structures reminiscent of mammalian early endosomes. In addition, the accumulation of novel plasma membrane invaginations where endocytosis is likely to occur were visualized in the mutants by electron microscopy using cationized ferritin as a marker for the endocytic pathway. This new screening strategy demonstrates a role for She4p and Pan1p in endocytosis, and provides a new general method for the identification of additional endocytosis mutants.     

Pmt-mediated O mannosylation stabilizes an essential component of the secretory apparatus, Sec20p, in Candida albicans

Sec20p is an essential endoplasmic reticulum (ER) membrane protein in yeasts, functioning as a tSNARE component in retrograde vesicle traffic. We show that Sec20p in the human fungal pathogen Candida albicans is extensively O mannosylated by protein mannosyltransferases (Pmt proteins). Surprisingly, Sec20p occurs at wild-type levels in a pmt6 mutant but at very low levels in pmt1 and pmt4 mutants and also after replacement of specific Ser/Thr residues in the lumenal domain of Sec20p. Pulse-chase experiments revealed rapid degradation of unmodified Sec20p (38.6 kDa) following its biosynthesis, while the stable O-glycosylated form (50 kDa) was not formed in a pmt1 mutant. These results suggest a novel function of O mannosylation in eukaryotes, in that modification by specific Pmt proteins will prevent degradation of ER-resident membrane proteins via ER-associated degradation or a proteasome-independent pathway.     

Ubiquitin ligase Hul5 is required for fragment-specific substrate degradation in endoplasmic reticulum-associated degradation

To identify new components of the protein quality control and degradation pathway of the endoplasmic reticulum (ER), we performed a growth-based genome-wide screen of about 5000 viable deletion mutants of the yeast Saccharomyces cerevisiae. As substrates we used two misfolded ER membrane proteins, CTL* and Sec61-2L, chimeric derivatives of the classical ER degradation substrates CPY* and Sec61-2. Both substrates contain a cytosolic Leu2 protein fusion, and stabilization of these substrates in ER-associated degradation-deficient strains enables a restored growth of the transformed LEU2-deficient deletion mutants. We identified the strain deleted for the ubiquitin chain elongating ligase Hul5 among the mutant strains with a strong growth phenotype. Here we show that Hul5 is necessary for the degradation of two misfolded ER membrane substrates. Although the degradation of their N-terminal parts is Hul5-independent, the breakdown of their C-terminal fragments requires the ubiquitin chain elongating ligase activity of Hul5. In the absence of Hul5, a truncated form of CTL*myc remains to a large extent embedded in the ER membrane. Hul5 activity promotes the interaction of this truncated CTL*myc with the AAA-ATPase Cdc48, which is known to pull proteins out of the ER membrane. This study unravels the stepwise elimination of the ER membrane-localized CTL*myc substrate. First, N-terminal, lumenal CPY* is transferred to the cytoplasm and degraded by the proteasome. Subsequently, the remaining C-terminal membrane-anchored part requires Hul5 for its effective extraction out of the endoplasmic reticulum and proteasomal degradation.     

The ankyrin repeat-containing protein Akr1p is required for the endocytosis of yeast pheromone receptors.

The Saccharomyces cerevisiae a-factor receptor (Ste3p) requires its C-terminal cytoplasmic tail for endocytosis. Wild-type receptor is delivered to the cell surface via the secretory pathway but remains there only briefly before being internalized and delivered to the vacuole for degradation. Receptors lacking all or part of the cytoplasmic tail are not subject to this constitutive endocytosis. We used the cytoplasmic tail of Ste3p as bait in the two-hybrid system in an effort to identify other proteins involved in endocytosis. One protein identified was Akr1p, an ankyrin repeat-containing protein. We applied three criteria to demonstrate that Akr1p is involved in the constitutive endocytosis of Ste3p. First, when receptor synthesis is shut off, akr1 delta cells retain the ability to mate longer than do AKR1 cells. Second, Ste3p half-life is increased by greater than 5-fold in akr1 delta cells compared with AKR1 cells. Third, after a pulse of synthesis, newly synthesized receptor remains at the cell surface in akr1 delta mutants, whereas it is rapidly internalized in AKR1 cells. Specifically, in akr1 delta mutants, newly synthesized receptor is accessible to exogenous protease, and by indirect immunofluorescence, the receptor is located at the cell surface. akr1 delta cells are also defective for endocytosis of the alpha-factor receptor (Ste2p). Despite the block to constitutive endocytosis exhibited by akr1 delta cells, they are competent to carry out ligand-mediated endocytosis of Ste3p. In contrast, akr1 delta cells cannot carry out ligand-mediated endocytosis of Ste2p. We discuss the implications for Akr1p function in endocytosis and suggest a link to the regulation of ADP-ribosylation proteins (Arf proteins).