Impaired proteasome function rescues thermosensitivity of yeast cells lacking the coatomer subunit epsilon-COP

Formation of COPI-coated transport vesicles requires a cytosolic protein complex consisting of seven subunits: alpha-, beta-, beta'-, gamma-, delta-, epsilon- and zeta-COP, collectively designated coatomer. The yeast Saccharomyces cerevisiae gene encoding the epsilon-COP subunit is known as SEC28/ANU2. anu2 null mutant cells (anu2Delta) are temperature-sensitive, and alpha-COP is rapidly degraded in these cells when they are shifted to the restrictive temperature. We isolated extragenic suppressors that rescue the temperature-sensitive growth defect of anu2Delta cells. Genetic analysis revealed that one of the suppressors is allelic to PRE8 (PRS4), which encodes a 20 S proteasome subunit. In the presence of a proteasome inhibitor, MG132, anu2Delta cells did not cease growth even at the restrictive temperature. Furthermore, MG132 inhibited the rapid decrease of alpha-COP levels in anu2Delta cells shifted to the restrictive temperature. However, secretion of certain proteins by these cells was impaired even in the presence of MG132. In conclusion, impairment of proteasome-dependent proteolysis rescued some, but not all, temperature-sensitive defects of anu2Delta cells. These results are discussed in terms of evidence that epsilon-COP plays a critical role in maintaining the structural integrity of alpha-COP.     

A subset of yeast vacuolar protein sorting mutants is blocked in one branch of the exocytic pathway.

Exocytic vesicles that accumulate in a temperature-sensitive sec6 mutant at a restrictive temperature can be separated into at least two populations with different buoyant densities and unique cargo molecules. Using a sec6 mutant background to isolate vesicles, we have found that vacuolar protein sorting mutants that block an endosome-mediated route to the vacuole, including vps1, pep12, vps4, and a temperature-sensitive clathrin mutant, missort cargo normally transported by dense exocytic vesicles, such as invertase, into light exocytic vesicles, whereas transport of cargo specific to the light exocytic vesicles appears unaffected. Immunoisolation experiments confirm that missorting, rather than a changed property of the normally dense vesicles, is responsible for the altered density gradient fractionation profile. The vps41Delta and apl6Delta mutants, which block transport of only the subset of vacuolar proteins that bypasses endosomes, sort exocytic cargo normally. Furthermore, a vps10Delta sec6 mutant, which lacks the sorting receptor for carboxypeptidase Y (CPY), accumulates both invertase and CPY in dense vesicles. These results suggest that at least one branch of the yeast exocytic pathway transits through endosomes before reaching the cell surface. Consistent with this possibility, we show that immunoisolated clathrin-coated vesicles contain invertase.     

Direct involvement of phosphatidylinositol 4-phosphate in secretion in the yeast Saccharomyces cerevisiae

The SEC14 gene encodes an essential phosphatidylinositol (PtdIns) transfer protein required for formation of Golgi-derived secretory vesicles in yeast. Suppressor mutations that rescue temperature-sensitive sec14 mutants provide an approach for determining the role of Sec14p in secretion. One suppressor, sac1-22, causes accumulation of PtdIns(4)P. SAC1 encodes a phosphatase that can hydrolyze PtdIns(4)P and certain other phosphoinositides. These findings suggest that PtdIns(4)P is limiting in sec14 cells and that elevation of PtdIns(4)P production can suppress the secretory defect. Correspondingly, we found that PtdIns(4)P levels were decreased significantly in sec14-3 mutants shifted to 37 degrees C and that sec14-3 cells could grow at an otherwise nonpermissive temperature (34 degrees C) when carrying a plasmid overexpressing PIK1, encoding one of two essential PtdIns 4-kinases. This effect is specific because overexpression of the other PtdIns 4-kinase gene (STT4) or a PtdIns 3-kinase gene (VPS34) did not rescue sec14-3 cells. To further address Pik1p function in secretion, two different pik1(ts) mutants were examined. Upon shift to restrictive temperature (37 degrees C), the PtdIns(4)P levels dropped by about 60% in both pik1(ts) strains within 1 h. During the same period, cells displayed a reduction (40-50%) in release of a secreted enzyme (invertase). However, similar treatment did not effect maturation of a vacuolar enzyme (carboxypeptidase Y). These findings indicate that, first, PtdIns(4)P limitation is a major contributing factor to the secretory defect in sec14 cells; second, Sec14p function is coupled to the action of Pik1p, and; third, PtdIns(4)P has an important role in the Golgi-to-plasma membrane stage of secretion.     

The yeast SLY gene products, suppressors of defects in the essential GTP-binding Ypt1 protein, may act in endoplasmic reticulum-to-Golgi transport.

It has been shown previously that defects in the essential GTP-binding protein, Ypt1p, lead to a block in protein transport from the endoplasmic reticulum (ER) to the Golgi apparatus in the yeast Saccharomyces cerevisiae. Here we report that four newly discovered suppressors of YPT1 deletion (SLY1-20, SLY2, SLY12, and SLY41) to a varying degree restore ER-to-Golgi transport defects in cells lacking Ypt1p. These suppressors also partially complement the sec21-1 and sec22-3 mutants which lead to a defect early in the secretory pathway. Sly1p-depleted cells, as well as a conditional lethal sly2 null mutant at nonpermissive temperatures, accumulate ER membranes and core-glycosylated invertase and carboxypeptidase Y. The sly2 null mutant under restrictive conditions (37 degrees C) can be rescued by the multicopy suppressor SLY12 and the single-copy suppressor SLY1-20, indicating that these three SLY genes functionally interact. Sly2p is shown to be an integral membrane protein.     

Early stages in the yeast secretory pathway are required for transport of carboxypeptidase Y to the vacuole

Temperature-sensitive secretory mutants (sec) of S. cerevisiae have been used to evaluate the organelles and cellular functions involved in transport of the vacuolar glycoprotein, carboxypeptidase Y (CPY). Others have shown that CPY (61 kd) is synthesized as an inactive proenzyme (69 kd) that is matured by cleavage of an 8 kd amino-terminal propeptide. sec mutants that are blocked in either of two early stages in the secretory process and accumulate endoplasmic reticulum or Golgi bodies also accumulate precursor forms of CPY when cells are incubated at the nonpermissive temperature (37°C). These forms are converted to a proper size when cells are returned to a permissive temperature (25°C). Vacuoles isolated from sec mutant cells do not contain the proCPY produced at 37°C. These results suggest that vacuolar and secretory glycoproteins require the same cellular functions for transport from the endoplasmic reticulum and from the Golgi body. The Golgi body represents a branch point in the pathway: from this organelle, vacuolar proenzymes are transported to the vacuole for proteolytic processing and secretory proteins are packaged into vesicles.     

COP I domains required for coatomer integrity, and novel interactions with ARF and ARF-GAP

We performed a systematic mapping of interaction domains on COP I subunits to gain novel insights into the architecture of coatomer. Using the two-hybrid system, we characterize the domain structure of the alpha-, beta'-, epsilon-COP and beta-, gamma-, delta-, zeta-COP coatomer subcomplexes and identify links between them that contribute to coatomer integrity. Our results demonstrate that the domain organization of the beta-, gamma-, delta-, zeta-COP subcomplex and AP adaptor complexes is related. Through in vivo analysis of alpha-COP truncation mutants, we characterize distinct functional domains on alpha-COP. Its N-terminal WD40 domain is dispensable for yeast cell viability and overall coatomer function, but is required for KKXX-dependent trafficking. The last approximately 170 amino acids of alpha-COP are also non-essential for cell viability, but required for epsilon-COP incorporation into coatomer and maintainance of normal epsilon-COP levels. Further, we demonstrate novel direct interactions of coatomer subunits with regulatory proteins: beta'- and gamma-COP interact with the ARF-GTP-activating protein (GAP) Glo3p, but not Gcs1p, and beta- and epsilon-COP interact with ARF-GTP. Glo3p also interacts with intact coatomer in vitro.     

Protein sorting in yeast: the localization determinant of yeast vacuolar carboxypeptidase Y resides in the propeptide

We have isolated cis-acting mutations in the gene encoding the yeast vacuolar protein carboxypeptidase Y (CPY) that result in missorting and aberrant secretion of up to 95% of newly synthesized CPY. The CPY polypeptides synthesized by these mutants use the late secretory pathway to exit the cell, since the late-acting sec1 mutation prevents their secretion. The mutant versions of CPY are secreted as the proCPY zymogen and are enzymatically activatable in vivo and in vitro. All the mutations, including small deletions and an amino acid substitution, map to the amino-terminal propeptide region and define a discrete yeast vacuolar localization domain whose integrity is required for efficient sorting of the CPY zymogen. Thus, the N-terminal propeptide of CPY carries out at least three functions: it mediates translocation across the endoplasmic reticulum, renders the enzyme inactive during transit, and targets the molecule to the vacuole.     

Loss of a GPI-anchored membrane protein Aah3p causes a defect in vacuolar protein sorting in Schizosaccharomyces pombe

Schizosaccharomyces pombe has four alpha-amylase homologs (Aah1p-Aah4p) with a glycosylphosphatidylinositol (GPI) modification site at the C-terminal end. Disruption mutants of aah genes were tested for mislocalization of vacuolar carboxypeptidase Y (CPY), and aah3Delta was found to secrete CPY. The conversion rate from pro- to mature CPY was greatly impaired in aah3Delta, and fluorescence microscopy inidicated that a sorting receptor for CPY, Vps10p, mislocalized to the vacuolar membrane. These results indicate that aah3Delta had a defect in the retrograde transport of Vps10p, and that Aah3p is the first S. pombe specific protein required for vacuolar protein sorting.     

Yeast secretory mutants that block the formation of active cell surface enzymes

Yeast cells secrete a variety of glycosylated proteins. At least two of these proteins, invertase and acid phosphatase, fail to be secreted in a new class of mutants that are temperature-sensitive for growth. Unlike the yeast secretory mutants previously described (class A sec mutants; Novick, P., C. Field, and R. Schekman, 1980, Cell., 21:205-420), class B sec mutants (sec 53, sec 59) fail to produce active secretory enzymes at the restrictive temperature (37 degrees C). sec 53 and sec 59 appear to be defective in reactions associated with the endoplasmic reticulum. Although protein synthesis continues at a nearly normal rate for 2 h at 37 degrees C, incorporation of [3H]mannose into glycoprotein is reduced. Immunoreactive polypeptide forms of invertase accumulate within the cell which have mobilities on SDS PAGE consistent with incomplete glycosylation: sec 53 produces little or no glycosylated invertase, and sec 59 accumulates forms containing 0-3 of the 9-10 N-linked oligosaccharide chains that are normally added to the protein. In addition to secreted enzymes, maturation of the vacuolar glycoprotein carboxypeptidase Y, incorporation of the plasma membrane sulfate permease activity, and secretion of the major cell wall proteins are blocked at 37 degrees C.     

In vitro reconstitution of intercompartmental protein transport to the yeast vacuole

Toward a detailed understanding of protein sorting in the late secretory pathway, we have reconstituted intercompartmental transfer and proteolytic maturation of a yeast vacuolar protease, carboxypeptidase Y (CPY). This in vitro reconstitution uses permeabilized yeast spheroplasts that are first radiolabeled in vivo under conditions that kinetically trap ER and Golgi apparatus-modified precursor forms of CPY (p1 and p2, respectively). After incubation at 25 degrees C, up to 45% of the p2CPY that is retained in the perforated cells can be proteolytically converted to mature CPY (mCPY). This maturation is specific for p2CPY, requires exogenously added ATP, an ATP regeneration system, and is stimulated by cytosolic protein extracts. The p2CPY processing shows a 5-min lag period and is then linear for 15-60 min, with a sharp temperature optimum of 25-30 degrees C. After hypotonic extraction, the compartments that contain p2 and mCPY show different osmotic stability characteristics as p2 and mCPY can be separated with centrifugation into a pellet and supernatant, respectively. Like CPY maturation in vivo, the observed in vitro reaction is dependent on the PEP4 gene product, proteinase A, which is the principle processing enzyme. After incubation with ATP and cytosol, mCPY was recovered in a vacuole-enriched fraction from perforated spheroplasts using Ficoll step-gradient centrifugation. The p2CPY precursor was not recovered in this fraction indicating that intercompartmental transport to the vacuole takes place. In addition, intracompartmental processing of p2CPY with autoactivated, prevacuolar zymogen pools of proteinase A cannot account for this reconstitution. Stimulation of in vitro processing with energy and cytosol took place efficiently when the expression of PEP4, under control of the GAL1 promoter, was induced then completely repressed before radiolabeling spheroplasts. Finally, reconstitution of p2CPY maturation was not possible with vps mutant perforated cells suggesting that VPS gene product function is necessary for intercompartmental transport to the vacuole in vitro.     

A role for clathrin in the sorting of vacuolar proteins in the Golgi complex of yeast.

We have investigated the role of clathrin in vacuolar protein sorting using yeast strains harboring a temperature-sensitive allele of clathrin heavy chain (chc1-ts). After a 5 min incubation at the non-permissive temperature (37 degrees C), the chc1-ts strains displayed a severe defect in the sorting of lumenal vacuolar proteins. Sorting of a vacuolar membrane protein, alkaline phosphatase, and transport to the surface of a cell wall protein, was not affected at 37 degrees C. In chc1-ts cells incubated at 37 degrees C, secretion of the missorted lumenal vacuolar protein carboxypeptidase Y (CPY) was blocked by the sec1 mutation which prevents fusion of secretory vesicles to the plasma membrane. Unexpectedly, chc1-ts cells incubated for extended periods at 37 degrees C regained the ability to sort CPY. Cells carrying deletions of the CHC1 gene (chc1 delta) also sorted CPY to the vacuole even when subjected to temperature shifts. Vacuolar delivery of CPY in chc1 delta cells was not blocked by sec1 suggesting that transport does not occur by secretion and endocytosis. These results provide in vivo evidence that clathrin plays a role in the Golgi complex in sorting of vacuolar proteins from the secretory pathway. With time, however, yeast cells lacking functional clathrin heavy chains are able to adapt in a way that allows restoration of vacuolar protein sorting in the Golgi complex. These conclusions clarify previous studies of chc1 delta cells which raised the possibility that clathrin is not involved in vacuolar protein sorting.     

A Role for Tlg1p in the Transport of Proteins within the Golgi Apparatus of Saccharomyces cerevisiae

Members of the syntaxin protein family participate in the docking-fusion step of several intracellular vesicular transport events. Tlg1p has been identified as a nonessential protein required for efficient endocytosis as well as the maintenance of normal levels of trans-Golgi network proteins. In this study we independently describe Tlg1p as an essential protein required for cell viability. Depletion of Tlg1p in vivo causes a defect in the transport of the vacuolar protein carboxypeptidase Y through the early Golgi. Temperature-sensitive (ts) mutants of Tlg1p also accumulate the endoplasmic reticulum/cis-Golgi form of carboxypeptidase Y at the nonpermissive temperature (38 degrees C) and exhibit underglycosylation of secreted invertase. Overexpression of Tlg1p complements the growth defect of vti1-11 at the nonpermissive temperature, whereas incomplete complementation was observed with vti1-1, further suggesting a role for Tlg1p in the Golgi apparatus. Overexpression of Sed5p decreases the viability of tlg1 ts mutants compared with wild-type cells, suggesting that tlg1 ts mutants are more susceptible to elevated levels of Sed5p. Tlg1p is able to bind His6-tagged Sec17p (yeast alpha-SNAP) in a dose-dependent manner and enters into a SNARE complex with Vti1p, Tlg2p, and Vps45p. Morphological analyses by electron microscopy reveal that cells depleted of Tlg1p or tlg1 ts mutants incubated at the restrictive temperature accumulate 40- to 50-nm vesicles and experience fragmentation of the vacuole.     

Gene dosage-dependent secretion of yeast vacuolar carboxypeptidase Y

The structural gene for yeast vacuolar carboxypeptidase Y (PRC1) has been cloned by complementation of the prc1-1 mutation. As much as an eightfold elevation in the level of carboxypeptidase Y (CPY) results when a multiple-copy plasmid containing the PRC1 gene is introduced into yeast. Unlike the situation with a single copy of PRC1 in which newly synthesized CPY is efficiently localized to the vacuole, plasmid-directed overproduction results in secretion of greater than 50% of the protein as the precursor form. Secretion is blocked in a mutant that is defective at a late stage in the transport of periplasmic proteins. Unlike normal cell surface glycoproteins, secreted CPY precursor acquires no additional oligosaccharide modifications beyond those that accompany normal transport to the vacuole. In the periplasm, the CPY precursor is proteolytically activated to an enzymatically active form by an enzyme that is unrelated to the vacuolar processing enzyme. These findings suggest that proper sorting and transport of CPY is saturable. This may reflect limiting amounts of a CPY-sorting receptor, or of CPY-modifying machinery that is essential for recognition by such a receptor.     

Yeast cys3 and gsh1 mutant cells display overlapping but non-identical symptoms of oxidative stress with regard to subcellular protein localization and CDP-DAG metabolism

In a screen for temperature-sensitive (37 degrees C) mutants of Saccharomyces cerevisiae that are defective in the proper localization of the Golgi transmembrane protein Emp47p, we uncovered a constitutive loss-of-function mutation in CYS3/STR1, the gene coding for cystathionine-gamma-lyase. We showed by immunofluorescence, sucrose-gradient analysis and quantitative Western analysis that the mutant mislocalized Emp47p to the vacuole at high temperature, while Golgi structures were apparently normal and biosynthetic routing of the vacuolar carboxypeptidase Y (CPY) and the plasma membrane GPI-anchored protein Gas1p were unaffected. The effect of high temperature on Emp47p localization, as well as the temperature sensitivity of the mutant strain on rich medium, appear to be caused by oxidative stress and are correlated with severe reductions in the intracellular levels of low-molecular-weight thiols. In accordance with this conclusion, cys3-2 mutant cells were more sensitive to the oxidizing agent 1-chloro-2,4-dinitrobenzene, which also aggravated the mislocalization of Emp47p observed at high temperature. Furthermore, all the phenotypes of the mutant were completely complemented by exogenous supply of the main low-molecular-weight thiol, glutathione (GSH) and, importantly, the thiol beta-mercaptoethanol reversed the temperature sensitivity of the mutant. A comparison of our mutant with a mutant defective in GSH synthesis showed that gsh1Delta cells were similar to wild-type cells under the stress conditions tested, with the exception of one novel oxidative stress-related phenotype that is observed in both cys3-2 and gsh1Delta mutant cells - a defect in CDP-DAG metabolism upon shift to the non-permissive temperature. As most of the stress-related phenotypes of cys3-2 mutant cells are more severe than those seen in gsh1Delta cells, we conclude that cysteine as such is required and sufficient to confer some degree of protection from oxidative stress in yeast cells.     

A novel immunodetection screen for vacuolar defects identifies a unique allele of VPS35 in S. cerevisiae

The late endosome and vacuole of yeast Saccharomyces cerevisiae are functionally equivalent to the mammalian late endosome and lysosome. The late endosome is the convergence point of the biosynthetic and endocytic trafficking to the vacuole. Here, we describe a novel immunodetection screen to isolate mutants defective in trafficking the soluble hydrolase carboxypeptidase Y (CPY) at the late endosome to vacuole interface (env mutants). Mutants exhibit vacuolar morphology and endocytosis defects as assayed by electron, fluorescent, and nomarski microscopy. In biochemical assays, they internally accumulate p2CPY in a dense membrane compartment lacking vacuolar properties yet display normal secretion phenotypes. The results suggest vacuolar morphology and function defects that are exclusively at the late endosome/vacuole interface. env mutants define five complementation groups. The first gene of the collection to be cloned, ENV1 is allelic to VPS35 whose established function is in retrograde trafficking from late endosome to trans-Golgi network (TGN). Microscopic, biochemical, and growth analyses establish that env1 is distinct from other alleles of VPS35 in vacuolar morphology, growth characteristics, and internal accumulation of p2CPY. Our results indicate that ENV genes may define new gene functions at the late endosome to vacuole interface.     

vac2: a yeast mutant which distinguishes vacuole segregation from Golgi-to-vacuole protein targeting.

We have isolated four yeast mutants that are unable to partition maternal vacuoles into growing buds. Three of these vacuole segregation (vac) mutants also mislocalize the vacuolar protease carboxypeptidase Y (CPY) to the cell surface, a phenotype previously reported for vac strains. A fourth mutant, vac2-1, exhibits a temperature-sensitive defect in vacuole segregation but does not show a defect in protein targeting from the Golgi apparatus to the vacuole. Haploid vac2-1 cells grown at the non-permissive temperature do not secrete CPY or a second vacuolar protease, proteinase A (PrA). Furthermore, newly synthesized precursors of CPY are converted to mature forms with similar kinetics in both vac2-1 and wild-type cells. In addition, invertase is secreted normally from vac2-1 cells, indicating that post-Golgi steps in the secretory pathway are not blocked in this mutant. These results suggest that VAC2 function is necessary for vacuole division and segregation in yeast but is not involved in vacuole protein sorting events at the Golgi apparatus.     

Compartmental organization of Golgi-specific protein modification and vacuolar protein sorting events defined in a yeast sec18 (NSF) mutant

The sec18 and sec23 secretory mutants of Saccharomyces cerevisiae have previously been shown to exhibit temperature-conditional defects in protein transport from the ER to the Golgi complex (Novick, P., S. Ferro, and R. Schekman, 1981. Cell. 25:461-469). We have found that the Sec18 and Sec23 protein functions are rapidly inactivated upon shifting mutant cells to the nonpermissive temperature (less than 1 min). This has permitted an analysis of the potential role these SEC gene products play in transport events distal to the ER. The sec-dependent transport of alpha-factor (alpha f) and carboxypeptidase Y (CPY) biosynthetic intermediates present throughout the secretory pathway was monitored in temperature shift experiments. We found that Sec18p/NSF function was required sequentially for protein transport from the ER to the Golgi complex, through multiple Golgi compartments and from the Golgi complex to the cell surface. In contrast, Sec23p function was required in the Golgi complex, but only for transport of alpha f out of an early compartment. Together, these studies define at least three functionally distinct Golgi compartments in yeast. From cis to trans these compartments contain: (a) An alpha 1----6 mannosyltransferase; (b) an alpha 1----3 mannosyltransferase; and (c) the Kex2 endopeptidase. Surprisingly, we also found that a pool of Golgi-modified CPY (p2 CPY) located in a compartment distal to the alpha 1----3 mannosyltransferase does not require Sec18p function for final delivery to the vacuole. This compartment appears to be equivalent to the Kex2 compartment as we show that a novel vacuolar CPY-alpha f-invertase fusion protein undergoes efficient Kex2-dependent cleavage resulting in the secretion of invertase. We propose that this Kex2 compartment is the site in which vacuolar proteins are sorted from proteins destined to be secreted.     

Ultracytochemical localization of the vacuolar marker enzymes alkaline phosphatase, adenosine triphosphatase, carboxypeptidase Y and aminopeptidase reveal new concept of vacuole biogenesis in Saccharomyces cerevisiae

Logarithmic cultures of Saccharomyces cerevisiae strains LBG H 1022, FL-100, X 2180 1A and 1B were studied together with the mutants pep4-3, sec18-1 and sec7-1. The necessary ultrastructural observations showed that, as a rule, juvenile vacuoles were formed de novo from perinuclear endoplasmic reticulum cisternae (ER) packed and inflated with electron-dense (polyanionic) matrix material. This process was disturbed solely in the sec18-1 mutant under non-permissive conditions. The vacuolar marker enzymes adenosine triphosphatase (ATPase) and alkaline phosphohydrolase (ALPase) were assayed by the ultracytochemical cerium precipitation technique. The neutral ATPase was active in vacuolar membranes and in the previously shown (coated) microglobules nearby. ALPase activity was detected in microglobules inside juvenile vacuoles, inside nucleus and in the cytoplasm as well as in the membrane vesicles and in the periplasm. The sites of vacuolar protease carboxypeptidase Y (CPY) activity were assayed using N-CBZ-L-tyrosine-4-methoxy-2-naphthyl-amide (CBZ-Tyr-MNA) as substrate and sites of the amino-peptidase M activity using Leu-MNA as substrate. Hexazotized p-rosaniline served as a coupler for the primary reaction product of both the above proteases (MNA) and the resulting azo-dye was osmicated during postfixation. The CPY reaction product was found in both polar layers of vacuolar membranes (homologous to ER) and in ER membranes enclosing condensed lipoprotein bodies which were taken up by the vacuoles of late logarithmic yeast. Both before and after the uptake into the vacuoles the bodies contained the CPY reaction product in concentric layers or in cavities. Microglobules with CPY activity were also observed. Aminopeptidase was localized in microglobules inside the juvenile vacuoles. These findings combined with the previous cytochemical localizations of polyphosphates and X-prolyl-dipeptidyl (amino)peptidase in S. cerevisiae suggest the following cytologic mechanism for the biosynthetic protein transport: coated microglobules convey metabolites and enzymes either to the cell surface for secretion or enter the vacuoles in all phases of the cell cycle. The membrane vesicles represent an alternative secretory mechanism present in yeast cells only during budding. The homology of the ER with the vacuolar membranes and with the surface membranes of the lipoprotein condensates (bodies) indicates a cotranslational entry of the CPY into these membranes. The secondary transfer of a portion of CPY into vacuoles is probably mediated by the lipoprotein uptake process.     

Characterization of genes required for protein sorting and vacuolar function in the yeast Saccharomyces cerevisiae.

To further our studies of protein sorting and biogenesis of the lysosome-like vacuole in yeast, we have isolated spontaneous mutations in 11 new VPL complementation groups, as well as additional alleles of the eight previously described VPL genes. These mutants were identified by selecting for cells that mislocalize vacuolar proteins to the cell surface. Morphological examination of the vpl mutants indicated that most contain vacuoles of normal appearance; however, some of the mutants generally lack a large vacuole, and instead accumulate smaller organelles. Of the 19 VPL complementation groups, 12 were found to be identical to 12 of 33 VPT complementation groups identified in a separate study. Moreover, the end1 mutant and all of the previously reported pep mutants, with the exception of pep4, were found to exhibit a profound vacuolar protein sorting defect, and complementation tests between the PEP, VPL VPT and END1 groups demonstrated that there are extensive overlaps between these groups. Collectively, mutants in these four collections define 49 complementation groups required to deliver or retain soluble vacuolar enzymes, including carboxypeptidase Y (CPY) and proteinase A. We have also isolated 462 new mutants that lack normal levels of vacuolar CPY activity. Among these latter mutants, only pep4 mutants were found to be specifically defective in vacuolar zymogen activation. We conclude that there is a large number of gene products required for sorting or retention of vacuolar proteins in yeast, and only a single gene, PEP4, that is essential for activation of CPY and other vacuolar zymogens.     

The Yeast v-SNARE Vti1p Mediates Two Vesicle Transport Pathways through Interactions with the t-SNAREs Sed5p and Pep12p

Membrane traffic in eukaryotic cells requires that specific v-SNAREs on transport vesicles interact with specific t-SNAREs on target membranes. We identified a novel Saccharomyces cerevisiae v-SNARE (Vti1p) encoded by the essential gene, VTI1. Vti1p interacts with the prevacuolar t-SNARE Pep12p to direct Golgi to prevacuolar traffic. vti1-1 mutant cells missorted and secreted the soluble vacuolar hydrolase carboxypeptidase Y (CPY) rapidly and reversibly when vti1-1 cells were shifted to the restrictive temperature. However, overexpression of Pep12p suppressed the CPY secretion defect exhibited by vti1-1 cells at 36°C. Characterization of a second vti1 mutant, vti1-11, revealed that Vti1p also plays a role in membrane traffic at a cis-Golgi stage. vti1-11 mutant cells displayed a growth defect and accumulated the ER and early Golgi forms of both CPY and the secreted protein invertase at the nonpermissive temperature. Overexpression of the yeast cis-Golgi t-SNARE Sed5p suppressed the accumulation of the ER form of CPY but did not lead to CPY transport to the vacuole in vti1-11 cells. Overexpression of Sed5p allowed growth in the absence of Vti1p. In vitro binding and coimmunoprecipitation studies revealed that Vti1p interacts directly with the two t-SNAREs, Sed5p and Pep12p. These data suggest that Vti1p plays a role in cis-Golgi membrane traffic, which is essential for yeast viability, and a nonessential role in the fusion of Golgi-derived vesicles with the prevacuolar compartment. Therefore, a single v-SNARE can interact functionally with two different t-SNAREs in directing membrane traffic in yeast.