The Deubiquitinating Enzyme Ubp1 Affects Sorting of the ATP-binding Cassette-Transporter Ste6 in the Endocytic Pathway

Carolin Schmitz^*, Andrea Kinner, and Ralf Kölling

Institut für Mikrobiologie, Heinrich-Heine-Universität Düsseldorf, D-40225 Düsseldorf, Germany

Submitted May 21, 2004; Revised December 10, 2004; Accepted December 23, 2004
Monitoring Editor: David Drubin

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

Deubiquitinating enzymes (Dubs) are potential regulators ofubiquitination-dependent processes. Here, we focus on a memberof the yeast ubiquitin-specific processing protease (Ubp) family,the Ubp1 protein. We could show that Ubp1 exists in two forms:a longer membrane-anchored form (mUbp1) and a shorter solubleform (sUbp1) that seem to be independently expressed from thesame gene. The membrane-associated mUbp1 variant could be localizedto the endoplasmic reticulum (ER) membrane by sucrose densitygradient centrifugation and by immunofluorescence microscopy.Overexpression of the soluble Ubp1 variant stabilizes the ATP-bindingcassette-transporter Ste6, which is transported to the lysosome-likevacuole for degradation, and whose transport is regulated byubiquitination. Ste6 stabilization was not the result of a generalincrease in deubiquitination activity, because overexpressionof Ubp1 had no effect on the degradation of the ER-associateddegradation substrate carboxypeptidase Y^* and most importantlyon Ste6 ubiquitination itself. Also, overexpression of anotheryeast Dub, Ubp3, had no effect on Ste6 turnover. This suggeststhat the Ubp1 target is a component of the protein transportmachinery. On Ubp1 overexpression, Ste6 accumulates at the cellsurface, which is consistent with a role of Ubp1 at the internalizationstep of endocytosis or with enhanced recycling to the cell surfacefrom an internal compartment.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

Many cellular proteins are modified by the attachment of the76-amino acid polypeptide ubiquitin (Hochstrasser, 1996; Hershkoand Ciechanover, 1998). The main role of ubiquitination is totarget proteins for degradation either directly by acting asa degradation signal that is recognized by the 26S proteasomeor indirectly by sorting membrane proteins into the lysosomal/vacuolardegradation pathway (Hicke, 1999). Ubiquitination of substrateproteins, which occurs by a cascade of enzymatic reactions,is reversible. Ubiquitin can again be removed from proteinsby deubiquitinating enzymes (Dubs). A large number of Dubs havebeen identified in various organisms that are either cysteineproteases or metalloproteases (Verma et al., 2002; Yao and Cohen,2002). The more classical cysteine proteases can again be dividedinto two groups: the ubiquitin C-terminal hydrolases (Uchs)that preferentially cleave ubiquitin from peptides and smalladducts (e.g., Yuh1 in yeast) and the extremely divergent familyof ubiquitin-specific processing proteases (Ubps) that cleaveubiquitin from protein substrates (Hochstrasser, 1996). Of the17 cysteine-protease–type Dubs in yeast 16 belong to theUbp class.

The degree of ubiquitination seems to be mainly regulated atthe level of ubiquitin attachment. However, evidence is accumulatingthat deubiquitination also can be important for the regulationof ubiquitination levels. Evidence has been presented that thedeubiquitinating enzyme Fat facets (Faf), which is involvedin eye development in Drosophila, acts as a substrate-specificregulator of ubiquitination of the epsin homologue Liquid facets(Lqf). Faf seems to prevent proteolysis of Lqf by counteractingits ubiquitination (Chen et al., 2002). Another example is theDub mUBPy from mouse that may play a role in controlling degradationof the Ras nucleotide exchange factor CDC25^Mm. Coexpressionof mUBPy with CDC25^Mm reduces ubiquitination of CDC25^Mm andincreases its half-life (Gnesutta et al., 2001). Another potentialregulator of ubiquitination is UCH-L1, one of the most abundantproteins in brain. Mutations in UCH-L1 may either increase ordecrease the susceptibility for Parkinson's disease by affectingthe turnover of ${alpha}$ -synuclein (Leroy et al., 1998; Liu et al.,2002).

In yeast, evidence for a regulatory role of Dubs has been presentedfor Ubp3. It has been shown that Ubp3 interacts with Sir4, acomponent of a complex required for silencing at the silentmating-type loci and at telomeres (Moazed and Johnson, 1996).Silencing is enhanced in ${Delta}$ ubp3 mutants, suggesting that Ubp3acts as an inhibitor of silencing. Furthermore, Ubp3 seems tohave a role in the pheromone response pathway in yeast (Wangand Dohlman, 2002). In addition, Ubp3 together with an additionalfactor Bre5 seems to regulate the stability of components ofthe COPI and COPII complexes in endoplasmic reticulum (ER)-to-Golgitrafficking (Cohen et al., 2003a,b).

We are mainly interested in the role of ubiquitination in membranetrafficking. Many ubiquitin-dependent processes, such as internalizationof cell surface proteins (Hicke, 1999), targeting of membraneproteins to multivesicular bodies (MVBs) (Katzmann et al., 2001;Losko et al., 2001; Reggiori and Pelham, 2001), retrovirus budding(Patnaik et al., 2000; Schubert et al., 2000; Strack et al.,2000), or ER-associated degradation (ERAD) (Hiller et al., 1996;Wiertz et al., 1996) occur at cellular membranes. To identifypotential regulators of ubiquitin-dependent processes at membranes,we looked for membrane-associated Dubs among the 16 yeast membersof the Ubp family (Kinner and Kölling, 2003). Althoughthe Ubps are in general hydrophilic proteins devoid of potentialmembrane spanning segments, a varying degree of membrane associationwas detected for most of them. Only one Ubp protein, Ubp16,was completely membrane associated. We could show that thisprotein is localized to the outer mitochondrial membrane. Thefunction of Ubp16 at mitochondria, however, is still unclear.Here, we focus on the Ubp1 protein, which showed a remarkablefractionation pattern in subcellular fractionation experiments.We demonstrate that Ubp1 exists in two forms, a membrane-anchoredform and a soluble form, which seem to be expressed independentlyfrom the same gene. The membrane-anchored form could be localizedto the ER membrane. Our studies further suggest that Ubp1 playsa role in protein trafficking in the early endocytic pathway.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

Strains and Plasmids
Yeast strains are listed in Table 1. Gene deletion or gene taggingwas accomplished by insertion of a polymerase chain reaction(PCR)-generated cassette into the yeast genome (Longtine etal., 1998). The changes were verified by PCR. The UBP1 genewas amplified by PCR with PfuUltra (Stratagene, La Jolla, CA)from chromosomal yeast DNA and inserted upstream of the 13mycsequence into the 2 µ-vector pRK722 (based on YEplac195;Gietz and Sugino, 1988) and into the CEN/ARS plasmid pRK717(based on YCplac33; Gietz and Sugino, 1988) to give plasmidspRK805 and pRK806. The 13myc fragment was obtained from pFA6a-13myc-His3MX6(Longtine et al., 1998). The correctness of the UBP1 sequencewas confirmed by sequencing. Based on these plasmids, UBP1 mutantswere generated by QuikChange PCR mutagenesis (Stratagene). InpRK851 (based on pRK806), the serine residues 530 and 531 werechanged to alanine; in pRK911 (based on pRK805) and pRK912 (basedon pRK806), methionine 67 was changed to serine; and in pRK982(based on pRK806) and pRK983 (based on pRK805), cysteine 110was changed to serine. The correctness of the mutagenized sequenceswas confirmed by sequencing. In pRK857, a PCR-generated UBP3fragment was cloned into the 2 µ-vector YEplac195. PlasmidpRK879 was generated from pRK805 by insertion of a stop codonbetween UBP1 ORF and the 13myc sequence. To construct pRK989,the UBP1 fragment of pRK879 was inserted into the 2 µ-vectorYEplac112 (Gietz and Sugino, 1988). To construct pRK590, a 5.5-kbHindIII/SacI STE6 fragment from pRK182 (Losko et al., 2001)was cloned into YEplac112. YEp112 contains a hemagglutinin (HA)-taggedubiquitin gene under the control of the CUP1 promoter (Hochstrasseret al., 1991). The STE2 gene was amplified by PCR with PfuUltra(Stratagene) from chromosomal yeast DNA and inserted upstreamof the 13myc sequence into the CEN/ARS plasmid pRK717 to giveplasmid pRK929. Plasmids pRK806-PGAL and pRK929-PGAL were generatedby in vivo recombination with a PCR-generated cassette (template,pFA6a-His3-PGAL1; Longtine et al., 1998). pRK806-PGAL containsthe GAL1 promoter directly upstream of the second ATG codonin the UBP1-13myc sequence.

View this table:
[in this window]
[in a new window]

Table 1. Yeast strains

Differential Centrifugation
Ten A₆₀₀ units of cells growing exponentially (A₆₀₀ = 0.4–0.7,2–4 x 10⁷ cells/ml) in YPD medium (1% yeast extract, 2%bacto peptone, 2% glucose) were harvested, washed in water,and resuspended in lysis buffer (0.3 M sorbitol, 50 mM HEPES,pH 7.5, and 10 mM NaN₃ + protease inhibitor cocktail). Cellswere lysed by vortexing with glass beads for 5 min at 4°C.Intact cells and cell debris were removed by centrifugationat 500 x g for 5 min. The cell extract was first spun at 13,000x g for 10 min to give the P13 pellet fraction and the S13 supernatant.The S13 fraction was then centrifuged at 100,000 x g for 1 hto give the P100 pellet and the S100 supernatant. To test forsolubility, equal aliquots of the extract were treated with1% Triton X-100, 1 M NaCl, or 0.1 M Na₂CO₃, pH 11, for 30 minon ice before centrifugation. Equal portions of the fractionswere assayed for the presence of proteins by Western blotting.

Flotation Gradients
Flotation gradients were essentially performed as describedin Bagnat et al. (2000). Briefly, cells were grown to logarithmicphase in YPD. Ten A₆₀₀ units were harvested by centrifugation,washed with water, and lysed by agitation with glass beads inTNE buffer (50 mM Tris, pH 7.4, 150 mM NaCl, and 5 mM EDTA +protease inhibitors). After removal of cell debris and intactcells by centrifugation at 500 x g for 5 min, 125 µl ofthe extract were mixed with 250 µl of 60% Optiprep solution(Axis-Shield, Oslo, Norway). The resulting 40% Optiprep fractionwas transferred to the bottom of a centrifugation tube and overlaidwith 600 µl of 30% Optiprep in TNE buffer and 100 µlof TNE. Then, the gradients were centrifuged at 77,000 rpm and4°C for 2 h in a TLA 100.2 rotor in a Beckman Tabletop ultracentrifuge.Six equal fractions were collected and assayed for the presenceof proteins by Western blotting.

Sucrose Density Gradient Centrifugation
One hundred milliliters of an exponentially growing YPD culturewas harvested by vacuum filtration onto nitrocellulose filtersand resuspended in 250 µl of STED10 [10% (wt/wt) sucrose,10 mM Tris, pH 7.6, 1 mM EDTA, pH 8.0, and 1 mM dithiothreitol+ protease inhibitors]. Cells were lysed by vortexing with glassbeads for 5 min at 4°C and diluted with 1 ml of STED10.Intact cells and cell debris were removed by centrifugationat 500 x g for 5 min. Cell extracts were loaded onto the topof a sucrose density gradient ranging from 20 to 40% sucrose(in STED buffer) and centrifuged for 14 h at 30,000 rpm in aBeckman SW40 rotor at 4°C. Eighteen gradient fractions werecollected and assayed for the presence of proteins by Westernblotting.

Immunofluorescence
The immunofluorescence experiments were performed as describedpreviously (Kölling and Hollenberg, 1994). Ste6-c-myc andUbp1-13myc were detected with 9E10 antic-myc primary antibodies(1:200; Covance, Berkeley, CA) and with fluorescein isothiocyanate(FITC)-conjugated anti-mouse secondary antibodies (1:300; Dianova,Hamburg, Germany). Fluorescence was observed with a Zeiss Axioskop(Carl Zeiss, Göttingen, Germany) equipped with a ZeissAxioCam digital camera by using an FITC filter set.

In Vivo Labeling of Cells and Immunoprecipitation
For the phosphorylation experiments, cells were grown overnightin SD-low phosphate medium (30 µM KH₂PO₄) to an A₆₀₀ $≤$ 0.8 (4 x 10⁷ cells/ml). Cells (5 x 10⁷) were labeled with 200µCi of [³²P]orthophosphate (PBS11; Amersham Biosciences,Piscataway, NJ) for 30 min at 30°C in 0.5 ml of SD-low phosphatemedium. The cells were washed in 10 mM NaN₃, resuspended in110 µl of lysis buffer (50 mM HEPES, 0.3 M sorbitol, 10mM NaN₃, pH 7.5, protease inhibitor cocktail, and 50 µg/mlRNase A) and vortexed for 3 min with 400 mg of glass beads.Pulse-chase experiments and immunoprecipitation were essentiallyperformed as described previously (Losko et al., 2001).

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

Ubp1 Exists in Two Forms That Can Be Separated by Cell Fractionation
For detection, Ubp1 was C-terminally tagged with a 13myc-epitopeby integration of a PCR-generated cassette at the 3' end ofthe chromosomal copy of the UBP1 gene. Ubp1 was examined formembrane association by differential centrifugation experiments.Cell extracts of the UBP1-13myc strain RKY1894 were fractionatedby two consecutive centrifugation steps at 13,000 and 100,000x g into P13 and P100 pellet fractions and a S100 supernatantfraction. Interestingly, two closely spaced Ubp1 bands wereobserved by Western blotting that could be separated by differentialcentrifugation (Figure 1A). The upper, slower migrating bandwas almost exclusively found in the P13 pellet, whereas thelower, faster migrating band was mainly found in the S100 fraction,which contains the soluble proteins. In addition, a small amountof the lower form also was detected in the P100 pellet fraction(Figure 1A). This result suggests that Ubp1 exists in two forms,a pelletable presumably membrane-associated form (mUbp1) anda soluble form (sUbp1).

View larger version (29K):
[in this window]
[in a new window]

Figure 1. Fractionation of Ubp1. (A) Cell extracts of the UBP1-13myc strain RKY1894 (lane 1, total cell extract) were centrifuged at 13,000 x g for 10 min to pellet the P13 fraction (lane 2). The supernatant was separated into P100 pellet fraction (lane 3) and S100 supernatant fraction (lane 4) by an additional centrifugation at 100,000 x g for 1 h. (B) Equal aliquots of the cell extract were treated with 1% Triton X-100 (lanes 4 and 5), 1 M NaCl (lanes 6 and 7), and 0.1 M Na₂CO₃, pH 11 (lanes 8 and 9) for 30 min on ice before a 1-h centrifugation at 100,000 x g. Lanes 1–3, untreated extract. Equal portions of the P100 (P) and S100 (S) fractions were analyzed for Ubp1-13myc. Lane 1, total cell extract. (C) Cell extracts of the UBP1-13myc strain RKY1894 were fractionated on Optiprep flotation gradients. Six fractions (lanes 1–6) were collected from the gradients (lanes 1–3, float fraction; lanes 4–6, nonfloat fraction). Fractions were analyzed by Western blotting with specific antibodies as indicated.

Depending on their intracellular localization, membrane proteinsare typically distributed in a characteristic way among theP13 and P100 fractions as exemplified by the two marker proteinsshown in Figure 1A, the ER marker protein Dpm1 and the endosomalmarker protein Pep12. Proteins associated with larger organellessuch as mitochondria, the vacuole, the ER, or the plasma membraneare mostly found in the P13 pellet, whereas proteins associatedwith the Golgi or with smaller vesicles are mostly found inthe P100 pellet. Typically, the endosomal marker Pep12 is evenlydistributed among the two pellet fractions (Becherer et al.,1996). This experiment, therefore, suggests that mUbp1 is localizedto a larger intracellular compartment and argues against anendosomal or Golgi localization of mUbp1.

Membrane association of mUbp1 was further investigated by treatingcell extracts with different reagents before centrifugationat 100,000 x g. As can be seen in Figure 1B, detergent treatment(1% Triton X-100) almost completely solubilized mUbp1 (shiftfrom P100 to S100), whereas the distribution of sUbp1 was unaffected.Reagents that are typically used to strip off peripheral membraneproteins from membranes (1 M NaCl and Na₂CO₃, pH 11) had noeffect on the distribution of mUbp1. Thus, mUbp1 behaves likean integral membrane protein. A small amount of sUbp1 also wasdetected in the P100 pellet fraction. This could be an indicationthat a certain fraction of sUbp1 also is membrane associated.However, the P100 fraction of sUbp1 proved to be resistant todetergent extraction. Thus, part of sUbp1 is either associatedwith detergent-resistant membranes ("rafts") or with a largerprotein complex.

Membrane association of mUbp1 is further supported by flotationanalysis on Optiprep gradients. Cell extracts of RKY1894 weremixed with a high-density Optiprep solution, placed at the bottomof a centrifuge tube, and overlaid with Optiprep solutions oflower density. During centrifugation, membranes float to thetop of the gradient due to their lower density, whereas solubleproteins remain behind in the lower part of the gradient. Thisis illustrated by the behavior of marker proteins (Figure 1C).The membrane protein alkaline phosphatase (ALP) was mainly foundin the top two fractions of the gradient, whereas the solubleprotein phosphoglycerate kinase (PGK) was mostly found in thelower three fractions. On these gradients, the two forms ofUbp1 showed a different fractionation pattern. Whereas sUbp1cofractionated with the soluble marker PGK, mUbp1 floated tothe top of the gradient like a typical membrane protein (Figure 1C).From these experiments, we conclude that Ubp1 exists intwo forms, a soluble form and a membrane-associated form.

To obtain information about the intracellular localization ofmUbp1, cell extracts of strain RKY1894 were fractionated onsucrose density gradients (Figure 2). Again, the two forms ofUbp1 were clearly separated on these gradients. sUbp1 cofractionatedwith the soluble proteins in the first few fractions of thegradient, whereas mUbp1 migrated further down the gradient.The distribution of mUbp1 was clearly distinct from the distributionof the vacuolar marker protein ALP and the plasma membrane markerPma1, which was found at the bottom of the tube due to the highdensity of the plasma membrane (our unpublished data). The endosomalmarker Pep12 displayed a complex fractionation pattern, whichcould reflect a localization of Pep12 to multiple compartmentsof different density. This is in line with the differentialcentrifugation experiment where Pep12 is distributed betweenlow- and high-speed pellet fractions (Figure 1A). Although mUbp1partially overlapped with the Pep12 distribution, the shapeof the mUbp1 peak was clearly different from the shape of thePep12 distribution. Therefore, mUbp1 does not seem to localizeto the Pep12 compartment(s). The closest match was observedbetween mUbp1 and the ER marker protein Dpm1. The match, however,was not perfect because the peak fraction of mUbp1 was shiftedby one fraction compared with Dpm1. But, this shift could bea quantification artifact because due to the close spacing ofthe bands, it was not possible to completely separate the mUbp1from the sUbp1 signal. So, sUbp1 contributes to a certain extentto the measured mUbp1 signal, especially in the upper part ofthe gradient. Alternatively, mUbp1 could be localized to a subdomainof the ER with a slightly different density. Despite these limitations,the sucrose density fractionation is most compatible with anER localization of mUbp1.

View larger version (32K):
[in this window]
[in a new window]

Figure 2. Fractionation of Ubp1 by density gradient centrifugation. A whole cell extract of the UBP1-13myc strain RKY1894 was fractionated on a sucrose density gradient [20–40% (wt/wt) sucrose; fraction 1, low sucrose density]. (A) Gradient fractions were analyzed for the presence of marker proteins by Western blotting with specific antibodies as indicated. (B) Densitometric quantification of the Western blot signals. The Western blot signal intensities were quantified with the program ImageJ. The strongest signals were set to 100%. Ubp1, diamonds; Dpm1, squares; Pep12, open circles; and ALP, filled circles.

Two Ubp1 Variants Are Encoded by the UBP1 Gene
Only a certain fraction of Ubp1 proved to be membrane associated.Notably, membrane association of Ubp1 was connected with alteredmobility on SDS-PAGs. What is the basis of this membrane association?Ubp1 could be anchored to membranes by posttranslational modificationssuch as prenylation or palmitoylation. Prenylation could beexcluded because no consensus sequences for prenylation (CAAX,CXC, CC, and CCXX) are found at the C terminus of Ubp1. Sensitivityto weak nucleophiles, including thiols, is a hallmark of thethioester linkage of palmitoylation (Roth et al., 2002). Membraneassociation of mUbp1, however, proved to be thiol resistant(our unpublished data). Thus, palmitoylation as the basis ofmembrane association of mUbp1 could be discounted as well. Wealso considered the possibility that monoubiquitination of Ubp1could account for the slower migrating Ubp1 band; however, wewere not able to detect an ubiquitin signal for Ubp1 (our unpublisheddata).

Because the most prevalent ways of posttranslational membraneattachment do not seem to be pertinent to mUbp1 membrane association,we looked for membrane anchors in the protein sequence itself.As can be seen from the hydropathy profile of Ubp1 (Figure 3A),a short hydrophobic stretch of $~$ 15 amino acids, which could potentiallyfunction as a membrane anchor, is found close to the N terminusof the Ubp1 sequence (Figure 3B). But, if Ubp1 contains a membraneanchor why is only a certain fraction of Ubp1 membrane associated?Two possibilities can be envisioned: either the membrane anchoris proteolytically cleaved from a certain fraction of Ubp1 ortwo different variants, with and without membrane anchor, aresynthesized from the same gene. As a corollary to the latterprediction, there should be two different promoters in frontof the UBP1 gene directing the expression of the two Ubp1 variants.If the second ATG codon in the UBP1 sequence is used as a translationalstart point, a protein 7883 Da smaller than full-length Ubp1will be generated. This corresponds exactly to the size difference(8 kDa) observed on Western blots. The smaller Ubp1 variantshould be soluble because it contains no longer the potentialmembrane anchor (Figure 3B). To test these predictions, we mutagenizedthe second ATG codon to a serine codon (TCG, M67S). If we removethe second ATG codon by mutagenesis, a shorter variant can nolonger be synthesized because the next ATG triplet in the sequenceis not in frame with the original UBP1 open reading frame (ORF).In line with this interpretation, only a single band was observedon Western blots for the Ubp1 M67S variant, which runs exactlyat the position of the upper Ubp1 band (Figure 3C). We alsoperformed the complementary experiment. The GAL1 promoter wasinserted in front of the second ATG codon thereby preventingexpression of the full-length UBP1 ORF. Under these conditions,only one band was observed that ran exactly at the positionof the lower Ubp1 band (Figure 3C). Together, these experimentsstrongly suggest that two different variants of Ubp1 are independentlyexpressed from the UBP1 gene, a longer membrane anchored form(mUbp1) and a shorter soluble form (sUbp1).

View larger version (22K):
[in this window]
[in a new window]

Figure 3. Two Ubp1 variants are encoded by the UBP1 gene. (A) Hydropathy profile of Ubp1. The hydrophobic peak corresponding to the potential TMD is marked by an arrow. (B) N-terminal part of the Ubp1 sequence. The putative TMD and the first and second methionine in the sequence are highlighted. The M67S mutation is indicated. (C) Cell extracts of strain JD52 transformed with different plasmids expressing different versions of the UBP1 gene were examined for Ubp1 by Western blotting. Lane 1, pRK912 (UBP1-13myc M67S); lane 2, pRK806 (UBP1-13myc); and lane 3, pRK806-PGAL (PGAL-UBP1-13myc). Lanes 1 and 2, glucose medium; lane 3, galactose medium. In lane 3, only one-fifth of the normal amount of cell extract was loaded.

The Membrane-anchored mUbp1 Variant Is Localized to the ER
The intracellular localization of 13myc tagged Ubp1 was studiedby immunofluorescence microscopy. With wild-type UBP1, a brightcytoplasmic staining was observed (Figure 4A), in agreementwith results obtained from a genome-wide protein localizationstudy (Huh et al., 2003). We were, however, especially interestedin the localization of the membrane-associated mUbp1 variant.But obviously, the strong cytoplasmic signal of the sUbp1 variantobscured the mUbp1 signal. With the constructs described inthe preceding section, we are now in a position to express thetwo Ubp1 variants separately. This allowed us to study the intracellularlocalization of mUbp1 by immunofluorescence microscopy independentlyfrom the sUbp1 background. With the 13myc-tagged Ubp1 M67S variant,expressed from a 2µ plasmid, a typical ER staining wasobserved (Figure 4B). The staining surrounded the nuclei, visualizedby 4,6-diamidino-2-phenylindole (DAPI) staining, and extendedfurther from the nuclei to the cell periphery. A similar, faintperinuclear staining also was observed with the single-copyUbp1 M67S variant (our unpublished data). These results arein agreement with the cell fractionation experiments that alsopoint to an ER localization of mUbp1.

View larger version (46K):
[in this window]
[in a new window]

Figure 4. Localization of Ubp1 by immunofluorescence. Ubp1 variants, encoded by pRK805 (UBP1-13myc) (A) and pRK911 (UBP1-13myc M67S) (B) were detected with anti-myc primary antibodies (9E10) and FITC-conjugated anti-mouse secondary antibodies. Top, FITC fluorescence; middle, staining of nuclei with DAPI; and bottom, phase contrast image.

What could be the function of mUbp1 at the ER membrane? Themost prominent ubiquitination-dependent process at the ER membraneis the ERAD pathway (Hampton, 2002). To test whether Ubp1 isinvolved in ERAD, we examined the effect of UBP1 deletion oroverexpression on the turnover of the ERAD substrate carboxypeptidaseY^* (CPY^*). CPY^* is a mutant form of CPY that is retained inthe ER in its core-glycosylated p1 form and degraded via theERAD pathway (Hiller et al., 1996). CPY^* turnover was examinedby pulse-chase experiments. In the wild-type strain JD52, CPY^*was degraded quickly with a half-life of $~$ 15 min (Figure 5),as reported previously (Hiller et al., 1996). A similar turnoverrate was observed in the UBP1 deletion strain RKY1932 and uponoverproduction of UBP1 from a 2µ plasmid (RKY1932/pRK879).The Ubp1 protein level was approximately fivefold higher inUBP1-overexpressing cells compared with single-copy UBP1 (ourunpublished data). As a positive control, we used a strain (RKY2015)that is deleted for a central component of the ERAD pathway,the ubiquitin-conjugating enzyme Ubc7 (Biederer et al., 1996).As expected, CPY^* was strongly stabilized in this strain. Fromthese experiments, we therefore conclude that Ubp1 probablydoes not play a general role in ERAD.

View larger version (67K):
[in this window]
[in a new window]

Figure 5. CPY^* turnover is unaffected by Ubp1. The turnover of CPY^* in different strains was examined by pulse-chase analysis. Cells were labeled with [³⁵S] Translabel for 15 min and chased with an excess of cold methionine and cysteine for the time intervals indicated. CPY^* was precipitated from cell extracts with polyclonal antibodies directed against CPY. Precipitated CPY^* was detected by autoradiography. The p1-CPY^* band is marked with an arrow. Strains used (from top to bottom) are RKY2019 (WT), RKY2020 ( ${Delta}$ ubp1), RKY2019/pRK879 (2µ-UBP1), and RKY2026 ( ${Delta}$ ubc7). All strains contain the prc1-1 allele (CPY^*).

UBP1 Overexpression Affects Ste6 Trafficking
The ABC-transporter Ste6 is transported to the yeast vacuolefor degradation via the MVB pathway (Losko et al., 2001). Traffickingof Ste6 and other cell surface proteins to the vacuole is regulatedby ubiquitination (Kölling and Hollenberg, 1994; Hicke,1999). As a deubiquitinating enzyme, Ubp1 is a potential regulatorof membrane protein trafficking in the endocytic pathway. Totest whether Ubp1 is involved in the regulation of Ste6 trafficking,we examined the effect of UBP1 deletion or overexpression onSte6 turnover. Again, Ste6 turnover was investigated by pulse-chaseexperiments. In the wild-type strain, JD52 Ste6 was quicklydegraded with a half-life of 18 min (Figure 6A), as reportedpreviously (Kölling and Hollenberg, 1994). Although Ste6turnover was unaffected by UBP1 deletion (Figure 6B, ${tau}$ = 20 min),Ste6 was stabilized approximately twofold by UBP1 overexpression(Figure 6C, ${tau}$ = 38 min). Ste6 turnover was not affected by overexpressionof a catalytically inactive Ubp1 variant (C110S), where theactive site cysteine had been replaced by serine (Figure 6D, ${tau}$ = 17 min). This indicates that the deubiquitinating activityof Ubp1 is required for Ste6 stabilization. To find out whichof the two Ubp1 forms is responsible for the observed stabilization,the 13myc-tagged mUbp1 and the sUbp1 variants were overexpressedseparately. To overexpress mUbp1, a 2µ plasmid carryingthe UBP1 M67S variant under the control of its own promoterwas introduced into the UBP1 deletion strain RKY1932. mUbp1was overexpressed approximately five-fold under these conditions(our unpublished data). The sUbp1 variant was expressed fromthe strong GAL1 promoter integrated into the chromosomal copyof the UBP1 gene (RKY2008), which leads to $~$ 10-fold overexpression(our unpublished data). As can be seen from Figure 6E, overexpressionof mUbp1 had no significant effect on Ste6 turnover ( ${tau}$ = 24 min).In contrast, overexpression of sUbp1 strongly stabilized Ste6(Figure 6G, ${tau}$ = 65 min). On galactose containing media, whichare required to induce the GAL1 promoter, Ste6 turnover wasapproximately twice as fast as on glucose-containing media (Figure 6F,half-life 12 min). Ste6 turnover was not affected by overexpressionof another deubiquitinating enzyme, UBP3, from a 2µ plasmid(our unpublished data), indicating that the observed UBP1 effectsmay be specific.

View larger version (54K):
[in this window]
[in a new window]

Figure 6. Effect of Ubp1 on Ste6 turnover. The turnover of Ste6 in different strains was examined by pulse-chase analysis. Cells were labeled with [³⁵S] Translabel for 15 min and chased with an excess of cold methionine and cysteine for the time intervals indicated. Ste6 was precipitated from cell extracts with polyclonal antibodies directed against Ste6. Precipitated Ste6 was detected by autoradiography. The Ste6 band is marked with an arrow. Background bands are labeled with asterisks. Strains used were JD52 (WT) (A), RKY1932 ( ${Delta}$ ubp1) (B), JD52/pRK805 (2µ-UBP1–13myc) (C), JD52/pRK983 (2µ-UBP1-13myc C110S) (D), JD52/pRK911 (2µ-UBP1-13myc M67S) (E), JD52 (WT/Gal) (F), and RKY2008 (PGAL-sUBP1-13myc) (G). Cells were either grown on glucose medium (A–E) or on galactose medium (F and G).

To see whether UBP1 overexpression affects other endocytic cargoproteins in addition to Ste6, we examined the effect of UBP1overexpression on the degradation of the ${alpha}$ -factor receptor Ste2.On binding of its ligand, ${alpha}$ -factor, Ste2 is internalized fromthe cell surface and degraded in the vacuole with a half-lifeof <10 min (Hicke and Riezman, 1996). Full-length Ste2, markedwith a 13myc-tag at its C terminus, was expressed under thecontrol of the GAL1 promoter from a single-copy plasmid. Expressionfrom the GAL1 promoter is induced by galactose and repressedby glucose in the growth media. A specific Ste2 signal was detectedon galactose-grown cells, whereas no signal was detectable onglucose medium (Figure 7). On addition of ${alpha}$ -factor, Ste2 becomeshyperphosphorylated and ubiquitinated (Hicke et al., 1998).Thus, in addition to the main Ste2 band, phosphorylated andubiquitinated forms with slower mobility can be detected. Ste2turnover was analyzed by a "Gal-depletion" experiment, i.e.,cells were first grown on galactose medium and then transferredto glucose medium to turn off expression form the GAL1 promoter.After transfer to glucose, ${alpha}$ -factor was added to the culture(t₀), and then samples were taken at 10-min intervals. As aloading control, the glycolytic enzyme PGK was detected by Westernblotting with specific antibodies. As can be seen in Figure 7,after ${alpha}$ -factor addition, Ste2, was quickly degraded in thecontrol cells (lanes 2–5), whereas Ste2 was stable incells overexpressing UBP1 (lanes 7–10). Thus, like Ste6,Ste2 is stabilized by overexpression of UBP1. This result suggeststhat UBP1 overexpression has a general effect on the traffickingof cargo proteins in the endocytic pathway.

View larger version (46K):
[in this window]
[in a new window]

Figure 7. Effect of Ubp1 on Ste2 turnover. Ste2 turnover was examined by a "Gal-depletion" experiment. JD52 transformed with pRK929-PGAL (PGAL1-STE2-13myc) and with YEplac112 (vector) (lanes 2–5) or pRK989 (2µ-UBP1) (lanes 7–10) were pregrown on galactose and then transferred to glucose medium. At t₀, ${alpha}$ -factor was added to 5 µM. Samples were taken at 10-min intervals and analyzed for Ste2 (top) by Western blotting with 9E10 antibodies and for PGK (bottom). The Ste2 and PGK bands are marked by arrows; phosphorylated (P) and ubiquitinated (Ub) forms are marked by bracket. Lanes 1 and 6, JD52/pRK929-PGAL/YEplac112 (lane 1) and JD52/pRK929-PGAL/pRK989 (lane 6) grown on medium containing 5% glucose.

Ubiquitination of Ste6 is required for its rapid degradationin the vacuole (Kölling and Hollenberg, 1994). Obviously,UBP1 overexpression could stabilize Ste6 by reducing its ubiquitination.To test this assumption, we examined the effect of UBP1 deletionor overexpression on Ste6 ubiquitination. To detect ubiquitination,Ste6 was immunoprecipitated from cell extracts prepared fromdifferent strains expressing STE6 from a 2µ plasmid. Inaddition, the strains were either transformed with an emptyvector or with a plasmid overexpressing UBP1. The immunoprecipitateswere examined for the presence of Ste6 and ubiquitin by Westernblotting (Figure 8). A ubiquitin signal can only be detectedin the immunoprecipitates, if ubiquitin is covalently attachedto Ste6. The ubiquitin signals were normalized to the amountof Ste6 present in the immunoprecipitates. A clear ubiquitinsignal could be detected in the wild-type strain that was absentin a strain that did not express Ste6. But, neither UBP1 deletion(92% of WT) nor UBP1 overexpression (119% of WT) had a significanteffect on the Ste6 ubiquitin signal. UBP1 overexpression, therefore,does not seem to exert its effect on Ste6 turnover through deubiquitinationof Ste6.

View larger version (77K):
[in this window]
[in a new window]

Figure 8. Effect of Ubp1 on Ste6 ubiquitination. Cell extracts were prepared from different strains transformed with a STE6 overexpressing plasmid (pRK590) or a vector control (YEplac112). In addition, the strains contained either an empty vector (YEplac195) or an UBP1-overexpressing plasmid (pRK805). Proteins immunoprecipitated with Ste6 antibodies were analyzed by Western blotting with anti-ubiquitin antibody (P4D1; Covance) (A) and with anti-Ste6 antibodies (B). Lanes 1 and 5, RKY959 ( ${Delta}$ ste6)/YEplac112/YEplac195; lanes 2 and 6, JD52 (WT)/pRK590/YEplac195; lanes 3 and 7, RKY1932 ( ${Delta}$ ubp1)/pRK590/YEplac195; and lanes 4 and 8, JD52/pRK590/pRK805.

We were interested to know at which step UBP1 overexpressioninterferes with Ste6 trafficking to the vacuole. To gain informationabout the step at which Ste6 accumulates upon UBP1 overexpression,Ste6 localization was examined by immunofluorescence microscopy.Under wild-type conditions, internal dots or patches were observedthat occasionally surrounded the vacuole (Figure 9A). Thesedots or patches presumably correspond to endosomal structures.On UBP1 overexpression, a striking, polar cell surface stainingwas observed. This suggests that UBP1 overexpression eitherinterferes with internalization from the cell surface or leadsto enhanced recycling to the cell surface from internal compartments.The same pattern was observed upon overexpression of the sUbp1variant from the GAL1 promoter (Figure 9B).

View larger version (37K):
[in this window]
[in a new window]

Figure 9. Effect of UBP1 overexpression on Ste6 localization. Ste6 localization was examined by immunofluorescence. (A) JD52 was transformed with the 2µ plasmid pYKS2 (Kuchler et al., 1993

) expressing c-myc–tagged Ste6. In addition, the strain contained either an empty vector (YEplac195) or an UBP1-overexpressing plasmid (pRK879). (B) JD52 or RKY2008 (PGAL-sUBP1-13myc), transformed with the 2µ plasmid pRK736 expressing an HA-tagged Ste6 variant, were grown on galactose medium to induce expression of sUbp1. Ste6 was detected with anti-myc or anti-HA primary antibodies and FITC-conjugated anti-mouse secondary antibodies. Top, FITC-fluorescence; bottom, phase contrast images.

Ubp1 Is Phosphorylated
By phosphoproteome analysis, a phosphorylated peptide was detectedthrough mass spectrometry that was assigned to Ubp1 (Ficarroet al., 2002). To confirm this finding, Ubp1 was directly examinedfor phosphorylation. To test for phosphorylation, 13myc-taggedUbp1 was immunoprecipitated from cell extracts prepared from[³²P]orthophosphate-labeled cells and examined by autoradiography.Two phosphorylated bands, which were absent in the negativecontrol, with spacing and intensity characteristic for the twoUbp1 forms, could be detected on the autoradiogram (our unpublisheddata). Thus, both forms of Ubp1 seem to be phosphorylated. Toexplore the role of phosphorylation for Ubp1 activity, we wantedto eliminate Ubp1 phosphorylation by mutagenizing the two predictedphosphorylation acceptor sites (serine 530, serine 531). However,when we examined the S530, 531A mutant for phosphorylation,it turned out that phosphorylation was unaffected. Thus, eitherthese two serine residues constitute only minor phosphorylationsites or the identified phosphopeptide was erroneously assignedto Ubp1.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

Here, we present evidence for a role of the deubiquitinatingenzyme Ubp1 in membrane protein trafficking in the endocyticpathway. We further show that the UBP1 gene codes for two variants,a longer membrane-anchored form (mUbp1) and a slightly smallersoluble form (sUbp1). Although not rigorously proven, our resultsstrongly suggest that these two forms are independently expressedfrom the same gene. The two Ubp1 forms differ in size by $~$ 8 kDa.If we assume that translation of the two forms starts at thefirst and the second ATG codon in the UBP1 ORF, two proteinswith exactly this size difference will be produced. This interpretationis supported by our mutagenesis experiment where we changedthe second ATG codon into a serine codon. With this mutation,the short form of Ubp1 was no longer produced. However, we cannotexclude the formal possibility that a specific protease cleavesat the position of the second methionine and that the M67S mutationinactivates this cleavage site. But, we consider this interpretationunlikely. There is precedent for a similar arrangement in yeast.Two forms of invertase are produced from the SUC2 gene: a longersecreted form with a hydrophobic signal sequence and a shorterintracellular form without signal sequence (Carlson and Botstein,1982). The two forms are expressed from two different promotersthat are regulated differently. It remains to be shown whetherthe two Ubp1 forms also are subjected to different kinds ofcontrol. Alternatively, the two forms could be expressed froma single mRNA by a leaky scanning mechanism of the ribosomeinitiating translation at either the first or the second AUGcodon. There also is precedent for such a mechanism (Kozak,1999).

By several criteria, we have localized the mUbp1 variant tothe ER membrane. In differential centrifugation experiments,mUbp1 was found exclusively in the P13 pellet fraction togetherwith the ER marker Dpm1; on sucrose density gradients, its fractionationpattern was most compatible with the distribution of Dpm1; andin immunofluorescence experiments, mUbp1 showed a typical ERpattern with perinuclear staining and tubular structures. Theunusually short putative transmembrane domain (TMD) of 15 aminoacids also fits into this picture. According to the bilayer-mediatedsorting model (Pelham and Munro, 1993), the length of the TMD,at least in part, mediates the localization of transmembraneproteins. As a general rule, the length of the TMDs increasesfrom inside to outside, if one moves along the secretory pathway.The shortest TMDs are observed in ER proteins ( $~$ 16 aa) and thelongest in plasma membrane proteins ( $~$ 25 aa) (Rayner and Pelham,1997).

What could be the function of mUbp1 at the ER membrane? It hasbeen suggested that the quite extensive family of deubiquitinatingenzymes in yeast could simply provide a high but relativelynonspecific ubiquitin-hydrolyzing activity (Amerik et al., 2000).Their main function would be to recycle ubiquitin from substratesdestined for degradation by the proteasome or the vacuole. Indeed,an important role in ubiquitin homeostasis has been demonstratedfor two Ubps, Ubp4/Doa4 (Swaminathan et al., 1999) and Ubp6(Chernova et al., 2003; Hanna et al., 2003). UBP4 and UBP6 mutantsare sensitive against various stress conditions, show a loweredfree ubiquitin level, and a reduced amount of large ubiquitinconjugates. Most of the phenotypes can be suppressed by overexpressionof ubiquitin. All other UBP mutants, however, display only mildphenotypes or no obvious phenotype at all (Amerik et al., 2000).This makes it seem unlikely that Ubps other than Ubp4 and Ubp6play a major role in ubiquitin homeostasis. With UBP1 mutants,we tested various growth conditions but could not detect anyobvious phenotype (our unpublished data). Also, the patternof ubiquitin conjugates from UBP1 mutants was indistinguishablefrom the wild-type pattern. We, therefore, consider it morelikely that mUbp1 performs a very specific function at the ERmembrane. Although, Ubp1 does not seem to play a general rolein ERAD, it could regulate the turnover of individual ERAD substrates.An example for such a control is provided by von Hippel-Lindauprotein-interacting deubiquitinating enzyme-1 (VDU1). VDU1 regulatesthe turnover of type 2 iodothyronine deiodinase (D2), an ER-localizedintegral membrane protein that is involved in the generationof biological active thyroid hormone (Curcio-Morelli et al.,2003). D2 has a short half-life due to ubiquitination and proteasomaldegradation and is stabilized by VDU1 through deubiquitination.

The two Ubp1 forms seem to carry out distinct functions. Althoughno phenotype could be detected for overexpression of mUbp1,overexpression of sUbp1 strongly stabilized Ste6. Transportof the a-factor transporter Ste6 to the yeast vacuole for degradationis regulated by ubiquitination (Kölling and Hollenberg,1994). In principle, a deubiquitinating enzyme such as Ubp1could prevent degradation by removing the ubiquitin tag fromSte6. Is Ubp1 specifically involved in the regulation of Ste6trafficking, or is Ste6 stabilization upon UBP1 overexpressionsimply the result of a general increase in deubiquitinatingactivity? Our findings argue for a specific role of Ubp1 inSte6 trafficking. First, overexpression of UBP1 had no effecton the turnover of the ERAD substrate CPY^*, which is dependenton ubiquitination and second, overexpression of another deubiquitinatingenzyme, Ubp3, did not affect Ste6 turnover. Finally and mostimportantly, the Ste6 ubiquitination level was unaffected byUBP1 overexpression. This suggests that the Ubp1 target is acomponent of the machinery required for Ste6 trafficking tothe vacuole. Which step in the trafficking pathway to the vacuolecould be affected by Ubp1? Ubiquitination has been implicatedin the internalization step of endocytosis at the plasma membrane(Hicke, 1999) and in sorting of membrane proteins into the MVBpathway (Katzmann et al., 2001; Losko et al., 2001; Reggioriand Pelham, 2001; Urbanowski and Piper, 2001). On UBP1 overexpression,Ste6 accumulates at the plasma membrane, which is consistentwith a role of Ubp1 at the internalization step of endocytosis.A different localization would have been expected, if Ubp1 affectedsorting into the MVB pathway (Losko et al., 2001). A block atthis stage usually leads to an accumulation of the affectedmembrane proteins at the vacuolar membrane.

Another possibility, which is also compatible with the observedcell surface accumulation, is enhanced recycling of Ste6 froman internal compartment. On UBP1 overexpression, Ste6 accumulatesat the cell surface in a polar manner, i.e., it is mainly localizedto the surface of the newly emerging daughter cell, the bud.A similar distribution has been observed for the v-SNARE Snc1(Lewis et al., 2000). For Snc1, it has been proposed that thisasymmetric distribution is achieved through "kinetic polarization,"i.e., through endocytic recycling and localized exocytosis (Valdez-Taubasand Pelham, 2003). A similar mechanism may be responsible forthe polar cell surface localization of Ste6 upon UBP1 overexpression.This notion is supported by our recent findings on the traffickingof ubiquitination-deficient Ste6 variants (our unpublished data).

What are the candidate proteins for Ubp1 deubiquitination? Inmammalian cells, several proteins that are involved in clathrin-mediatedendocytosis, such as epsin, Eps15, and Hrs, have been shownto be ubiquitinated (van Delft et al., 1997; Klapisz et al.,2002; Polo et al., 2002). These proteins carry ubiquitin-interactingmotifs (Hofmann and Falquet, 2001) that also seem to be intimatelylinked with their ubiquitination. There is evidence that deubiquitinationmay be involved in the regulation of the early endocytic pathway.The deubiquitinating enzyme Faf of Drosophila specifically regulatesthe turnover of the epsin homologue Lqf by counteracting itsubiquitination (Chen et al., 2002), and another deubiquitinatingenzyme, mouse UBPY, interacts with Hrs-binding protein, a proteinthat tightly associates with Hrs (Kato et al., 2000). In yeast,proteins corresponding to epsin (Ent1, Ent2), Eps15 (Ede1),and Hrs (Vps27) exist. However, so far no ubiquitination ofthese proteins has been reported. Still, they are prime candidatesfor Ubp1 targets. These targets remain to be identified.

ACKNOWLEDGMENTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

We thank Thomas Sommer for the CPY^* integration plasmid. Wealso are grateful to Karin Krapka for technical assistance andto Stefanie Huppert and Agnes Pawelec for help. This work wassupported by Deutsche Forschungsgemeinschaft grant Ko 963/3-2(to R. K.).

Footnotes

This article was published online ahead of print in MBC in Press(http://www.molbiolcell.org/cgi/doi/10.1091/mbc.E04-05-0425)on January 5, 2005.

^* Present address: Institut für Pathologie, Heinrich-Heine-UniversitätDüsseldorf, Moorenstr. 5, D-40225 Düsseldorf, Germany

Present address: Max-Planck-Institut für Molekulare Physiologie,Postfach 500247, D-44202 Dortmund, Germany

Address correspondence to: Ralf Kölling (ralf.koelling{at}uni-duesseldorf.de).

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

Amerik, A. Y., Li, S. J., and Hochstrasser, M. ((2000). ). Analysis of the deubiquitinating enzymes of the yeast Saccharomyces cerevisiae. Biol. Chem. 381, , 981-992.[CrossRef][Medline]

Bagnat, M., Keranen, S., Shevchenko, A., and Simons, K. ((2000). ). Lipid rafts function in biosynthetic delivery of proteins to the cell surface in yeast. Proc. Natl. Acad. Sci. USA 97, , 3254-3259.[Abstract/Free Full Text]

Becherer, K. A., Rieder, S. E., Emr, S. D., and Jones, E. W. ((1996). ). Novel syntaxin homologue, Pep12p, required for the sorting of lumenal hydrolases to the lysosome-like vacuole in yeast. Mol. Biol. Cell 7, , 579-594.[Abstract]

Biederer, T., Volkwein, C., and Sommer, T. ((1996). ). Degradation of subunits of the Sec61p complex, an integral component of the ER membrane, by the ubiquitin-proteasome pathway. EMBO J. 15, , 2069-2076.[Medline]

Carlson, M., and Botstein, D. ((1982). ). Two differentially regulated mRNAs with different 5' ends encode secreted with intracellular forms of yeast invertase. Cell 28, , 145-154.[CrossRef][Medline]

Chen, X., Zhang, B., and Fischer, J. A. ((2002). ). A specific protein substrate for a deubiquitinating enzyme: liquid facets is the substrate of Fat facets. Genes Dev. 16, , 289-294.[Abstract/Free Full Text]

Chernova, T. A., Allen, K. D., Wesoloski, L. M., Shanks, J. R., Chernoff, Y. O., and Wilkinson, K. D. ((2003). ). Pleiotropic effects of Ubp6 loss on drug sensitivities and yeast prion are due to depletion of the free ubiquitin pool. J. Biol. Chem. 278, , 52102-52115.[Abstract/Free Full Text]

Cohen, M., Stutz, F., Belgareh, N., Haguenauer-Tsapis, R., and Dargemont, C. ((2003a). ). Ubp3 requires a cofactor, Bre5, to specifically de-ubiquitinate the COPII protein, Sec23. Nat. Cell Biol. 5, , 661-667.[CrossRef][Medline]

Cohen, M., Stutz, F., and Dargemont, C. ((2003b). ). Deubiquitination, a new player in Golgi to endoplasmic reticulum retrograde transport. J. Biol. Chem. 278, , 51989-51992.[Abstract/Free Full Text]

Curcio-Morelli, C., Zavacki, A. M., Christofollete, M., Gereben, B., de Freitas, B. C., Harney, J. W., Li, Z., Wu, G., and Bianco, A. C. ((2003). ). Deubiquitination of type 2 iodothyronine deiodinase by von Hippel-Lindau protein-interacting deubiquitinating enzymes regulates thyroid hormone activation. J. Clin. Investig. 112, , 189-196.[CrossRef][Medline]

Ficarro, S. B., McCleland, M. L., Stukenberg, P. T., Burke, D. J., Ross, M. M., Shabanowitz, J., Hunt, D. F., and White, F. M. ((2002). ). Phosphoproteome analysis by mass spectrometry and its application to Saccharomyces cerevisiae. Nat. Biotechnol. 20, , 301-305.[CrossRef][Medline]

Gietz, R. D., and Sugino, A. ((1988). ). New yeast-Escherichia coli shuttle vectors constructed with in vitro mutagenized yeast genes lacking six-base pair restriction sites. Gene 74, , 527-534.[CrossRef][Medline]

Gnesutta, N., Ceriani, M., Innocenti, M., Mauri, I., Zippel, R., Sturani, E., Borgonovo, B., Berruti, G., and Martegani, E. ((2001). ). Cloning and characterization of mouse UBPy, a deubiquitinating enzyme that interacts with the Ras guanine nucleotide exchange factor CDC25(Mm)/Ras-GRF1. J. Biol. Chem. 276, , 39448-39454.[Abstract/Free Full Text]

Hampton, R. Y. ((2002). ). ER-associated degradation in protein quality control and cellular regulation. Curr. Opin. Cell Biol. 14, , 476-482.[CrossRef][Medline]

Hanna, J., Leggett, D. S., and Finley, D. ((2003). ). Ubiquitin depletion as a key mediator of toxicity by translational inhibitors. Mol. Cell. Biol. 23, , 9251-9261.[Abstract/Free Full Text]

Hershko, A., and Ciechanover, A. ((1998). ). The ubiquitin system. Annu. Rev. Biochem. 67, , 425-479.[CrossRef][Medline]

Hicke, L. ((1999). ). Gettin'down with ubiquitin: turning off cell-surface receptors, transporters and channels. Trends Cell. Biol. 9, , 107-112.[CrossRef][Medline]

Hicke, L., and Riezman, H. ((1996). ). Ubiquitination of a yeast plasma membrane receptor signals its ligand-stimulated endocytosis. Cell 84, , 277-287.[CrossRef][Medline]

Hicke, L., Zanolari, B., and Riezman, H. ((1998). ). Cytoplasmic tail phosphorylation of the ${alpha}$ -factor receptor is required for its ubiquitination and internalization. J. Cell Biol. 141, , 349-358.[Abstract/Free Full Text]

Hiller, M. M., Finger, A., Schweiger, M., and Wolf, D. H. ((1996). ). ER degradation of a misfolded luminal protein by the cytosolic ubiquitin-proteasome pathway. Science 273, , 1725-1728.[Abstract/Free Full Text]

Hochstrasser, M. ((1996). ). Ubiquitin-dependent protein degradation. Annu. Rev. Genet. 30, , 405-439.[CrossRef][Medline]

Hochstrasser, M., Ellison, M. J., Chau, V., and Varshavsky, A. ((1991). ). The short-lived MAT ${alpha}$ 2 transcriptional regulator is ubiquitinated in vivo. Proc. Natl. Acad. Sci. USA 88, , 4606-4610.[Abstract/Free Full Text]

Hofmann, K., and Falquet, L. ((2001). ). A ubiquitin-interacting motif conserved in components of the proteasomal and lysosomal protein degradation systems. Trends Biochem. Sci. 26, , 347-350.[CrossRef][Medline]

Huh, W. K., Falvo, J. V., Gerke, L. C., Carroll, A. S., Howson, R. W., Weissman, J. S., and O'Shea, E. K. ((2003). ). Global analysis of protein localization in budding yeast. Nature 425, , 686-691.[CrossRef][Medline]

Kato, M., Miyazawa, K., and Kitamura, N. ((2000). ). A deubiquitinating enzyme UBPY interacts with the Src homology 3 domain of Hrs-binding protein via a novel binding motif PX(V/I)(D/N)RXXKP. J. Biol. Chem. 275, , 37481-37487.[Abstract/Free Full Text]

Katzmann, D. J., Babst, M., and Emr, S. D. ((2001). ). Ubiquitin-dependent sorting into the multivesicular body pathway requires the function of a conserved endosomal protein sorting complex, ESCRT-I. Cell 106, , 145-155.[CrossRef][Medline]

Kinner, A., and Kölling, R. ((2003). ). The yeast deubiquitinating enzyme Ubp16 is anchored to the outer mitochondrial membrane. FEBS Lett. 549, , 135-140.[CrossRef][Medline]

Klapisz, E., Sorokina, I., Lemeer, S., Pijnenburg, M., Verkleij, A. J., and van Bergen en Henegouwen, P. M. ((2002). ). A ubiquitin-interacting motif (UIM) is essential for Eps15 and Eps15R ubiquitination. J. Biol. Chem. 277, , 30746-30753.[Abstract/Free Full Text]

Kölling, R., and Hollenberg, C. P. ((1994). ). The ABC-transporter Ste6 accumulates in the plasma membrane in a ubiquitinated form in endocytosis mutants. EMBO J. 13, , 3261-3271.[Medline]

Kozak, M. ((1999). ). Initiation of translation in prokaryotes and eukaryotes. Gene 234, , 187-208.[CrossRef][Medline]

Kuchler, K., Dohlman, H. G., and Thorner, J. ((1993). ). The a-factor transporter (STE6 gene product) and cell polarity in the yeast Saccharomyces cerevisiae. J. Cell Biol. 120, , 1203-1215.[Abstract/Free Full Text]

Leroy, E., et al. ((1998). ). The ubiquitin pathway in Parkinson's disease. Nature 395, , 451-452.[CrossRef][Medline]

Lewis, M. J., Nichols, B. J., Prescianotto-Baschong, C., Riezman, H., and Pelham, H. R. ((2000). ). Specific retrieval of the exocytic SNARE Snc1p from early yeast endosomes. Mol. Biol. Cell 11, , 23-38.[Abstract/Free Full Text]

Liu, Y., Fallon, L., Lashuel, H. A., Liu, Z., and Lansbury, P. T., Jr. ((2002). ). The UCH-L1 gene encodes two opposing enzymatic activities that affect a-synuclein degradation and Parkinson's disease susceptibility. Cell 111, , 209-218.[CrossRef][Medline]

Longtine, M. S., McKenzie, A., 3rd, Demarini, D. J., Shah, N. G., Wach, A., Brachat, A., Philippsen, P., and Pringle, J. R. ((1998). ). Additional modules for versatile and economical PCR-based gene deletion and modification in Saccharomyces cerevisiae. Yeast 14, , 953-961.[CrossRef][Medline]

Losko, S., Kopp, F., Kranz, A., and Kölling, R. ((2001). ). Uptake of the ATP-Binding Cassette (ABC) transporter Ste6 into the yeast vacuole is blocked in the doa4 mutant. Mol. Biol. Cell 12, , 1047-1059.[Abstract/Free Full Text]

Moazed, D., and Johnson, D. ((1996). ). A deubiquitinating enzyme interacts with SIR4 and regulates silencing in S. cerevisiae. Cell 86, , 667-677.[CrossRef][Medline]

Patnaik, A., Chau, V., and Wills, J. W. ((2000). ). Ubiquitin is part of the retrovirus budding machinery. Proc. Natl. Acad. Sci. USA 97, , 13069-13074.[Abstract/Free Full Text]

Pelham, H. R., and Munro, S. ((1993). ). Sorting of membrane proteins in the secretory pathway. Cell 75, , 603-605.[CrossRef][Medline]

Polo, S., Sigismund, S., Faretta, M., Guidi, M., Capua, M. R., Bossi, G., Chen, H., De Camilli, P., and Di Fiore, P. P. ((2002). ). A single motif responsible for ubiquitin recognition and monoubiquitination in endocytic proteins. Nature 416, , 451-455.[CrossRef][Medline]

Rayner, J. C., and Pelham, H. R. ((1997). ). Transmembrane domain-dependent sorting of proteins to the ER and plasma membrane in yeast. EMBO J. 16, , 1832-1841.[CrossRef][Medline]

Reggiori, F., and Pelham, H. R. ((2001). ). Sorting of proteins into multivesicular bodies: ubiquitin-dependent and -independent targeting. EMBO J. 20, , 5176-5186.[CrossRef][Medline]

Roth, A. F., Feng, Y., Chen, L., and Davis, N. G. ((2002). ). The yeast DHHC cysteine-rich domain protein Akr1p is a palmitoyl transferase. J. Cell Biol. 159, , 23-28.[Abstract/Free Full Text]

Schubert, U., Ott, D. E., Chertova, E. N., Welker, R., Tessmer, U., Princiotta, M. F., Bennink, J. R., Krausslich, H. G., and Yewdell, J. W. ((2000). ). Proteasome inhibition interferes with gag polyprotein processing, release, and maturation of HIV-1 and HIV-2. Proc. Natl. Acad. Sci. USA 97, , 13057-13062.[Abstract/Free Full Text]

Strack, B., Calistri, A., Accola, M. A., Palu, G., and Gottlinger, H. G. ((2000). ). A role for ubiquitin ligase recruitment in retrovirus release. Proc. Natl. Acad. Sci. USA 97, , 13063-13068.[Abstract/Free Full Text]

Swaminathan, S., Amerik, A. Y., and Hochstrasser, M. ((1999). ). The Doa4 deubiquitinating enzyme is required for ubiquitin homeostasis in yeast. Mol. Biol. Cell 10, , 2583-2594.[Abstract/Free Full Text]

Urbanowski, J. L., and Piper, R. C. ((2001). ). Ubiquitin sorts proteins into the intralumenal degradative compartment of the late-endosome/vacuole. Traffic 2, , 622-630.[CrossRef][Medline]

Valdez-Taubas, J., and Pelham, H. R. ((2003). ). Slow diffusion of proteins in the yeast plasma membrane allows polarity to be maintained by endocytic cycling. Curr. Biol. 13, , 1636-1640.[CrossRef][Medline]

van Delft, S., Govers, R., Strous, G. J., Verkleij, A. J., and van Bergen en Henegouwen, P. M. ((1997). ). Epidermal growth factor induces ubiquitination of Eps15. J. Biol. Chem. 272, , 14013-14016.[Abstract/Free Full Text]

Verma, R., Aravind, L., Oania, R., McDonald, W. H., Yates, J. R., 3rd, Koonin, E. V., and Deshaies, R. J. ((2002). ). Role of Rpn11 metalloprotease in deubiquitination and degradation by the 26S proteasome. Science 298, , 611-615.[Abstract/Free Full Text]

Wang, Y., and Dohlman, H. G. ((2002). ). Pheromone-dependent ubiquitination of the mitogen-activated protein kinase kinase Ste7. J. Biol. Chem. 277, , 15766-15772.[Abstract/Free Full Text]

Wiertz, E. J., Tortorella, D., Bogyo, M., Yu, J., Mothes, W., Jones, T. R., Rapoport, T. A., and Ploegh, H. L. ((1996). ). Sec61-mediated transfer of a membrane protein from the endoplasmic reticulum to the proteasome for destruction. Nature 384, , 432-438.[CrossRef][Medline]

Yao, T., and Cohen, R. E. ((2002). ). A cryptic protease couples deubiquitination and degradation by the proteasome. Nature 419, , 403-407.[CrossRef][Medline]

This article has been cited by other articles: