Efficient Cargo Sorting by ESCRT-I and the Subsequent Release of ESCRT-I from Multivesicular Bodies Requires the Subunit Mvb12

Matt Curtiss, Charles Jones, and Markus Babst

Department of Biology, University of Utah, Salt Lake City, UT 84112-9202

Submitted July 10, 2006; Revised October 26, 2006; Accepted November 20, 2006
Monitoring Editor: Sandra Lemmon

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The endosomal sorting complex required for transport (ESCRT)-Iprotein complex functions in recognition and sorting of ubiquitinatedtransmembrane proteins into multivesicular body (MVB) vesicles.It has been shown that ESCRT-I contains the vacuolar proteinsorting (Vps) proteins Vps23, Vps28, and Vps37. We identifiedan additional subunit of yeast ESCRT-I called Mvb12, which seemsto associate with ESCRT-I by binding to Vps37. Transient recruitmentof ESCRT-I to MVBs results in the rapid degradation of Mvb12.In contrast to mutations in other ESCRT-I subunits, which resultin strong defects in MVB cargo sorting, deletion of MVB12 resultedin only a partial sorting phenotype. This trafficking defectwas fully suppressed by overexpression of the ESCRT-II complex.Mutations in MVB12 did not affect recruitment of ESCRT-I toMVBs, but they did result in delivery of ESCRT-I to the vacuolarlumen via the MVB pathway. Together, these observations suggestthat Mvb12 may function in regulating the interactions of ESCRT-Iwith cargo and other proteins of the ESCRT machinery to efficientlycoordinate cargo sorting and release of ESCRT-I from the MVB.

INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Eukaryotic cells continuously remove transmembrane proteinsfrom the plasma membrane by endocytosis and deliver them tothe lumen of the lysosome for degradation (for review, see Gruenbergand Stenmark, 2004; Katzmann et al., 2002). The topologicalproblem of degrading transmembrane proteins in the lumen ofthe lysosome is solved by the formation of endosomal structurescalled multivesicular bodies (MVBs), which are formed by invaginationand budding of vesicles from the limiting endosomal membraneinto the lumen of the endosome. During this process, endosomaltransmembrane proteins destined for degradation are sorted intoforming vesicles and upon MVB fusion with the lysosome/vacuole,they are delivered to the lumen of the compartment, whereasothers are maintained on the limiting membrane. A variety ofstudies indicate that monoubiquitination serves as a signalthat directs protein cargo into the MVB pathway (Babst, 2005;Katzmann et al., 2002).

Sorting of endocytosed cell surface proteins through the MVBpathway plays an essential role in maintaining proper cell surfaceprotein composition. In addition, this pathway acts to quicklyand dramatically change the protein composition of the cellsurface during processes such as differentiation and adaptation.For example, growth factor signaling is regulated in part bythe controlled endocytosis and degradation of growth factorreceptors, a process that is disrupted in pathological statesof uncontrolled cellular proliferation in certain types of cancer(Di Fiore and Gill, 1999; Babst et al., 2000; Ceresa and Schmid,2000; Thompson et al., 2005; Vaccari and Bilder, 2005). In additionto protein degradation, the MVB pathway also functions in thetargeting and transport of lysosomal resident proteins. Forexample, in yeast the membrane-associated vacuolar enzyme carboxypeptidaseS (CPS) is delivered from the trans-Golgi via MVBs to the lumenof the vacuole, the yeast organelle corresponding to the mammalianlysosome where it acts as a lumenal protease (Odorizzi et al.,1998). Thus, the MVB pathway also plays an important role inmaintaining the function of the lysosomal/vacuolar compartment.Furthermore, MVBs have been shown to play an essential rolein the immune response of mammals where they function in antigenpresentation by dendritic cells and in the formation of exosomes(Murk et al., 2002).

Both MVB vesicle formation and sorting of ubiquitinated MVBcargo depends on the function of a group of at least 16 conservedproteins that were originally identified in the yeast Saccharomycescerevisiae as class E vacuolar protein sorting (Vps) proteins(Babst, 2005). Deletion of each of the class E VPS genes inyeast results in the accumulation of endosomal cargo in largestructures adjacent to the vacuole, called class E compartments(Raymond et al., 1992). This distinctive phenotype allows rapididentification of MVB sorting mutants in yeast. In additionto the morphological phenotype, in class E vps mutants transmembraneproteins such as CPS that are normally sorted to the vacuolarlumen are mislocalized to the limiting membrane of the vacuole(Odorizzi et al., 1998). Furthermore, the endosomal defectsin class E vps mutants result in impaired transport of solublevacuolar hydrolases from the trans-Golgi to endosomes, whichultimately leads to the secretion of a portion of the newlysynthesized enzymes (Raymond et al., 1992).

The majority of the class E Vps proteins are constituents ofthree separate hetero-oligomeric protein complexes called endosomalsorting complex required for transport (ESCRT)-I, ESCRT-II,and ESCRT-III and the Vps4 ATPase complex. The ESCRT proteincomplexes are transiently recruited from the cytoplasm to theendosomal membrane where they function in transmembrane proteinsorting and the formation of MVB vesicles. The ESCRT-I proteincomplex is recruited to the MVB by Vps27, a class E Vps proteinthat localizes to the endosome by binding to the lipid phosphatidylinositol3-phosphate (Bache et al., 2003; Katzmann et al., 2003). Onthe endosomal membrane both ESCRT-I and Vps27 bind to ubiquitinatedendosomal cargo (Katzmann et al., 2001; Pornillos et al., 2002;Bilodeau et al., 2003; Swanson et al., 2003; Sundquist et al.,2004; Teo et al., 2004; Hirano et al., 2006). In addition, ESCRT-Iinteracts with ESCRT-II, which initiates the oligomerizationof at least four small coiled-coil proteins, resulting in theformation of the ESCRT-III complex (Babst et al., 2002b; Teoet al., 2006). ESCRT-III is a large endosome-associated structurethat seems to function in the concentration of MVB cargo (Babstet al., 2002a). After protein sorting has been completed, themultimeric AAA-type ATPase Vps4 binds to ESCRT-III and disassemblesthe ESCRT-III complex in an ATP-dependent manner (Babst et al.,1998, 2002a).

ESCRT-I is a 350-kDa protein complex that has been shown tobe composed of the three class E Vps proteins: Vps23, Vps28,and Vps37 (Babst et al., 2000; Katzmann et al., 2001). However,expression of these subunits in Escherichia coli does not resultin the formation of a 350-kDa complex, suggesting that additionalunidentified subunits might be necessary for the formation ofESCRT-I in yeast (Kostelansky et al., 2006; Teo et al., 2006).In this publication, we present evidence for a fourth subunitof the yeast ESCRT-I complex, called Mvb12. Loss of Mvb12 resultsin a partial defect in MVB sorting and the mistargeting of ESCRT-Ito the vacuolar lumen. These data suggest that Mvb12 is notan essential factor for ESCRT-I function but that it may berequired for efficient cargo sorting and the release of ESCRT-Ifrom the MVB.

MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Materials
Monoclonal antibodies specific for the hemagglutinin (HA) epitopeand green fluorescent protein (GFP) were purchased from Covance(Princeton, NJ). Polyclonal antisera against Snf7 (Babst etal., 1998) and Vps23 (Babst et al., 2000) have been characterizedpreviously.

Strains and Media
S. cerevisiae strains used in this work are listed in Table 1.Yeast strains were grown in standard yeast extract-peptone-dextrose(YPD) or synthetic medium supplemented with essential aminoacids as required for maintenance of plasmids (YNB) (Shermanet al., 1979). The deletion strains were constructed by transforminga yeast strain with a DNA fragment containing the HIS3 or URA3gene flanked by 50 base pairs specific for the 5' and 3' regionof the corresponding gene. Yeast cells were selected for thepresence of the URA3 or HIS3 gene, and the deletions were confirmedby PCR analysis of the chromosomal DNA.

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Table 1. Strains and plasmids used in this study

DNA Manipulations
Recombinant DNA work was performed using standard protocols(Sambrook et al., 1989

). Transformation of S. cerevisiae wasdone by the lithium acetate method as described in Ito et al.(1983)

. The plasmids used in this study are listed in Table 1.The MVB12 gene was obtained by polymerase chain reaction (PCR)amplification of SEY6210 chromosomal DNA and inserted into theEcoRI/BamHI sites of pRS416, resulting in the plasmid pMB238.For the construction of pMB240, pCJ2, and pMC26, a DNA fragmentcoding for three HA epitopes was ligated with PCR products containingeither MVB12 or VPS37, respectively, and inserted into BamHI/SalI-digestedpRS416 or pRS426 vector. pMB239 and pMB306 were constructedby ligating a PCR product containing MVB12 with a GFP-containingfragment from the vector pEGFP-C1 (Clontech, Mountain View,CA) into the BamHI/SalI sites of the vectors pRS416 and pRS426.

Experimental Procedures
For native immunoprecipitation experiments, 10 OD₆₀₀ equivalentsof yeast cells were spheroplasted and then osmotic lysed in1 ml of phosphate-buffered saline (PBS) (8 g/l NaCl, 0.2 g/lKCl, 1.44 g/l Na₂HPO₄, and 0.24 g/l KH₂PO₄, pH 7.2) containingprotease inhibitors. The resulting cell extracts were centrifugedat 15,000 x g for 5 min. The resulting supernatant was incubatedwith antibodies (1/250 anti-HA antibody) for 1.5 h at 4°C.The antibodies were isolated by adding GammaBind G-Sepharose(GE Healthcare, Little Chalfont, Buckinghamshire, United Kingdom).After incubation for 1 h at 4°C, the Sepharose was washedthree times with PBS containing 0.5% Tween 20, and the antibodiestogether with the bound antigen were eluted by boiling the Sepharosein SDS-PAGE sample buffer. The resulting fractions were analyzedby SDS-PAGE and Western blotting. Vps23-ProtA was affinity purifiedfrom cell extract using IgG-Sepharose (GE Healthcare). Preparationof cell extract, incubation with the Sepharose, washes, andsample elution were performed as described for the immunoprecipitationexperiments. Immunofluorescence microscopy was performed onfixed spheroplasted cells as described in Babst et al. (1998).Fluorescence microscopy was performed on a deconvolution microscope(DeltaVision, Applied Precision, Issaquah, WA). For gel filtrationanalysis, yeast cells were spheroplasted and lysed in PBS containing0.1 mM 4-(2-aminoethyl)benzenesulfonyl fluoride and proteaseinhibitor cocktail (Complete; Roche Molecular Biochemicals,Indianapolis, IN). The lysate was centrifuged at 100,000 x g,and the resulting supernatant ( $~$ 2 mg of protein) was loaded ona Sephacryl S300 column (16/60; GE Healthcare) and separatedin presence of PBS. Subcellular fractionations were performedas described previously (Babst et al., 1997). Total cell extractsfor Western blot analysis were obtained by glass bead lysisof yeast from 6 ml of culture (OD₆₀₀ = 0.5) in SDS-PAGE samplebuffer (2% SDS, 0.1 M Tris, pH 6.8, 10% glycerol, 0.01% bromphenolblue, and 5% $beta$ -mercaptoethanol).

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Identification of Mvb12
A global analysis of protein localization in yeast identifieda group of uncharacterized proteins that are localized to endosomalcompartments (Huh et al., 2003). We tested the correspondingyeast deletion strains for phenotypes that are indicative ofMVB mutations. Our studies identified the open-reading frameYGR206w as a factor required for the MVB sorting pathway (seephenotypic analysis in later sections of this article). YGR206wencodes a 12-kDa protein and therefore, we named this gene MVB12.Mvb12 is a basic protein (pI 8.35) that contains no obviousstructural motifs and evolutionarily is poorly conserved. Noclear MVB12 homologues are identified in higher eukaryotes.Sequence homology searches identify uncharacterized open-readingframes in other genomes of fungal species as potential MVB12homologues. However, even among different yeast species thesequence conservation of Mvb12 is poor.

Mvb12 Transiently Localizes to MVBs
To study the localization of Mvb12, we constructed MVB12-GFP,a functional C-terminal GFP fusion of MVB12 (Supplemental Figure1). We expressed this fusion protein in different strains andanalyzed these strains by fluorescence microscopy (Figure 1A).Consistent with the results of the global protein localizationstudy, we observed that in wild-type cells Mvb12-GFP localizedto the cytoplasm and to small compartments consistent with endosomes.

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Figure 1. Localization of Mvb12 to MVBs is dependent on Vps27 and ESCRT-I. (A) Fluorescent microscopy of yeast strains (wild type [WT], MBY66; vps4 ${Delta}$ , MBY64; vps4 ${Delta}$ /vps27 ${Delta}$ , MBY22; and vps4 ${Delta}$ /vps37 ${Delta}$ , MCY19) expressing MVB12-GFP (pMB239). White arrows indicate class E compartments, aberrant endosomal structures present in class E vps mutants. (B) Immunofluorescence microscopy of vps4 ${Delta}$ (MBY3) and vps4 ${Delta}$ vps27 ${Delta}$ (MBY22) expressing MVB12-GFP (pMB239) demonstrates that colocalization of Mvb12 with endosome-associated ESCRT-III subunit Snf7 is dependent on Vps27. The Snf7 protein was visualized using specific anti-Snf7 antibody and fluorescently labeled secondary antibody. (C) Fluorescence microscopy of WT and vps4 ${Delta}$ (MBY3) strains expressing VPS23-RFP (pMB320) and MVB12-GFP (pMB321) demonstrates colocalization of Mvb12 with ESCRT-I.

The AAA-type ATPase Vps4 functions in the dissociation of theESCRTs from MVBs; therefore, mutations in VPS4 result in theaccumulation of the ESCRT machinery on aberrant endosomal membranes,the class E compartments (Figure 1A, arrows; Babst et al., 1998

,2002a

). The deletion of VPS4 resulted in the redistributionof Mvb12-GFP from the cytoplasm to larger compartments adjacentto vacuoles, consistent with class E compartments. Furthermore,by immunofluorescence microscopy we observed colocalizationof Mvb12-GFP with the ESCRT-III subunit Snf7 in these cells,indicating that in vps4 ${Delta}$ Mvb12-GFP accumulates on endosomal compartments(Figure 1B). Interestingly, we observed that the endosomal accumulationof Mvb12-GFP in vps4 ${Delta}$ was dependent on the presence of Vps27(Figure 1A). In vps4 ${Delta}$ vps27 ${Delta}$ cells, Mvb12-GFP localized mainlyto the cytoplasm and a minor pool associated with smaller dispersedcompartments. These compartments do not colocalize with Snf7,suggesting that they are not late endosomal structures (Figure 1B).Previous studies have shown that ESCRT-I localizes to the endosomalmembrane by binding to Vps27 and that ESCRT-I accumulates onthe membrane in a VPS4 deletion strain (Bache et al., 2003

;Katzmann et al., 2003

). Therefore, our localization studiessuggested that Mvb12 might be associated with ESCRT-I. Thisidea was further corroborated by the observation that red fluorescentprotein (RFP)-tagged Vps23 and Mvb12-GFP colocalized in bothwild-type and vps4 ${Delta}$ strains (Figure 1C). Furthermore, in strainsdeleted for the ESCRT-I subunit vps37 ${Delta}$ the fluorescent signalof Mvb12-GFP was dramatically reduced compared with other strainbackgrounds (Figure 1A). This observation suggested that Mvb12-GFPis unstable in ESCRT-I mutants, a result consistent with Mvb12being an ESCRT-I subunit.

Mvb12 Is a Subunit of the ESCRT-I Complex
To further study the effect of ESCRT mutations on the stabilityof Mvb12, we constructed a functional C-terminal HA-tagged Mvb12(Mvb12-HA; Supplemental Figure 1) and expressed this fusionprotein in wild type and mutant strain backgrounds. Cell extractswere prepared and analyzed for the presence of Mvb12-HA by Westernblot (Figure 2A). The analysis of wild-type cells showed twospecific bands, a major band at $~$ 15 kDa that corresponds to thepredicted molecular mass of Mvb12-HA (12 kDa for Mvb12 plus3 kDa for HA-tag) and a minor band at $~$ 20 kDa, which may be amodified form of Mvb12-HA (Mvb12-HA*; Figure 2A). A similarband pattern was observed with cell extracts from strains deletedfor VPS4, VPS27, VPS36 (encoding an ESCRT- II subunit), andSNF7 (encoding an ESCRT-III subunit). In contrast, cell extractsfrom the ESCRT-I mutant strains vps23 ${Delta}$ , vps28 ${Delta}$ , and vps37 ${Delta}$ exhibiteda dramatically reduced amount of the major, 15-kDa band, confirmingthe observation by microscopy that Mvb12 is unstable in ESCRT-Imutants. However, the amount of the modified form of Mvb12-HAremained similar in all mutant strains (Figure 2A). To determinewhere this modification occurs, we studied the cellular distributionof Mvb12-HA and Mvb12-HA* by subcellular fractionation. Forthis purpose, we prepared cell extracts by spheroplasting andosmotic lysis and separated the extract by centrifugation at15,000 x g into a soluble fraction (S) and a pellet fraction(P). Previous studies have shown that under these conditions,the MVB-associated protein pool is found in the pellet, whereasthe cytoplasmic fraction remains in the supernatant (Babst etal., 1998, 2002a). The Western blot analysis of the fractionationsamples showed that in wild-type cells Mvb12-HA is mainly foundin the soluble, cytoplasmic fraction, whereas in cells deletedfor VPS4 an increased amount of Mvb12-HA is observed in themembrane bound fraction (Figure 2B). These results are consistentwith the Mvb12-GFP localization observed by microscopy, althoughthe redistribution to the membrane in vps4 ${Delta}$ is less pronouncedthan expected from the microscopy data (Figure 1A). Similarly,ESCRT-I has been shown by microscopy to accumulate on endosomalmembranes in vps4 ${Delta}$ (Figure 7A; Katzmann et al., 2001); however,only a small portion of Vps23 is found in the membrane fractionof this strain (Figure 2B). A likely explanation for this discrepancybetween the two methods is that during the fractionation procedure,peripheral proteins such as ESCRT-I might partially dissociatefrom the membrane.

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Figure 2. Mvb12 is unstable in ESCRT-I mutants and physically interacts with the ESCRT-I complex. (A) Western blot analysis using anti-HA antibodies of total cell extracts from yeast strains expressing MVB12-HA (pMB240) or as a negative control (con.) MVB12 (pMB238). The strains used are described in Table 1. (B) Subcellular fractionation of yeast strains expressing MVB12-HA either from a low copy (pMB240) or a high copy (2µ, pCJ2) plasmid. The resulting supernatant (S) and pellet (P) fractions were analyzed by Western blot for the presence of Mvb12-HA and Vps23. (C) Extracts from wild-type cells expressing MVB12 (negative control) or MVB12-HA were used for an immunoprecipitation experiment using anti-HA antibodies. Samples of the immunoprecipitated material (bound, lanes 1 and 2) and the remaining supernatants (lanes 5 and 6) were analyzed by Western blot for the presence of Mvb12-HA and Vps23. Extracts from wild-type yeast expressing MVB12-HA in addition to VPS23 (negative control) or VPS23-ProtA were subjected to affinity purification by using IgG-Sepharose. The resulting enriched material (lanes 3 and 4) and the remaining supernatants (lanes 7 and 8) were analyzed by Western blot for the presence of Mvb12-HA and Vps23.

As expected from our previous results, the deletion of the VSP23resulted in a reduced amount of Mvb12-HA in both the solubleand the pelletable pool (Figure 2B). In contrast to Mvb12-HAthe amount and localization of the modified form Mvb12-HA* isnot effected by the deletions of either VPS4 or VPS23. In allstrains, Mvb12-HA* is found exclusively in the pelletable fraction.This result suggested that the modification of Mvb12-HA mightoccur on the endosomal membrane and that the modified pool ofMvb12-HA may not be associated with ESCRT-I. This is furthersupported by the observation that in cells overexpressing Mvb12-HA,the majority of the protein is found in the pellet in the modifiedform (Figure 2B). The nature of the modification is not known.However, based on the size shift Mvb12-HA* could represent aphosphorylated or monoubiquitinated form of Mvb12.

These data are consistent with the model that Mvb12 is a subunitof the ESCRT-I protein complex. To further test this model,we studied a potential physical interaction between Mvb12 andESCRT-I by immunoprecipitation experiments (Figure 2C). We preparedextracts from cells expressing either MVB12 (negative control)or MVB12-HA and performed immunoprecipitations under nativeconditions by using anti-HA antibodies. The Western blot analysisof the resulting samples demonstrated the specific coimmunoprecipitationof Vps23 with Mvb12-HA (Figure 2C, lane 2). No Vps23 was immunoprecipitatedfrom the Mvb12-containing control extract (Figure 2C, lane 1).A similar result was obtained by IgG-affinity purification.Cell extracts of strains expressing MVB12-HA together with VPS23or a functional protein A-tagged VPS23 (VPS23-ProtA) were incubatedwith IgG-Sepharose, and the bound material was tested for thepresence of Vps23 and Mvb12-HA. The data showed a specific copurificationof Mvb12-HA with Vps23-ProtA (Figure 2C, lane 4), whereas noenrichment of Mvb12-HA was observed from the VPS23-expressingcontrol extract (Figure 2C, lane 3). As a control for the presenceof Mvb12-HA and Vps23 in the extracts, we performed Westernblots of the supernatant after immunoprecipitation or affinitypurification (Figure 2C, lanes 5–8). In summary, bothimmunoprecipitation and IgG-affinity purification experimentsindicated a physical interaction between Mvb12 and ESCRT-I,supporting the notion that Mvb12 is a subunit of the ESCRT-Icomplex.

Finally, an extract from wild-type cells expressing MVB12-HAwas separated on a gel filtration column, and the resultingfractions were analyzed by Western blot for the presence ofMvb12-HA and the ESCRT-I subunit Vps23. The results indicateda native molecular mass of $~$ 350 kDa for Mvb12-HA similar to thesize of ESCRT-I (as indicated by Vps23; Figure 3A, gels 1 and2, and D). Furthermore, in a strain deleted for MVB12 we observeda shift in the size range of the ESCRT-I subunits Vps23 andVps37-HA to $~$ 170 kDa (Figure 3A, gels 3 and 4, and D). Together,these protein interaction and gel filtration data strongly suggestthat Mvb12 is a subunit of the ESCRT-I complex.

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Figure 3. Gel filtration experiments suggest that Mvb12 associates with ESCRT-I via the subunit Vps37. (A) Cytosol from different yeast strains expressing either MVB12-HA (pMB240) or HA-MVB12 (pMB301) was separated by gel filtration (Sephacryl S300), and the resulting fractions were analyzed by Western blot for the presence of Mvb12-HA, HA-Mvb12, and Vps23. Gels 8 and 9 show the results of the gel filtration analysis of wild type expressing MVB12-HA after 2 h of cycloheximide treatment. (B) Detailed analysis of gel filtration experiments from Figure 3A. Bars above the gels indicate the pooled fractions used in Figure 3A gels 2, 3, and 8. (C) Total cell extracts were prepared from yeast expressing MVB12-HA at different times after treatment with cycloheximide (0, 1, and 2 h) and analyzed by Western blot using anti-HA and anti-Vps23 antibodies. After 2 h of cycloheximide treatment the cells were prepared for gel filtration analysis and the extract loaded onto the column (L) was analyzed by Western blot. The result of this gel filtration analysis is shown in A (gels 8 and 9). (D) The table summarizes the apparent molecular masses of the analyzed proteins relative to the standard proteins thyroglobulin (670 kDa), ferritin (440 kDa), aldolase (158 kDa), albumin (67 kDa), ovalbumin (44 kDa) and myoglobin (17 kDa) (see A).

Mvb12 Seems to Associate with ESCRT-I via Vps37
Deletion of VPS37 results in the formation of a stable ESCRT-Isubcomplex of $~$ 125 kDa that has been shown to contain Vps23 andVps28 (Figure 3A, gel 6; Kostelansky et al., 2006

; Teo et al.,2006

). As shown in Figure 2A, Mvb12 is unstable in this mutantbackground, suggesting that Mvb12 associates with ESCRT-I viaVps37. To detect Mvb12 in vps37 ${Delta}$ , we transformed the mutant strainwith a plasmid expressing from the CPS1 promoter a functionalN-terminal fusion of MVB12 with the HA tag (Supplemental Figure1). The resulting fusion protein HA-Mvb12, like Mvb12-HA, isunstable in vps37 ${Delta}$ , but because of the strong CPS1 promoter HA-Mvb12is detectable by Western blot. Cell extract from vps37 ${Delta}$ expressingHA-MVB12 was separated by gel filtration, and Western blot analysisidentified small amounts of HA-Mvb12 in the size range of 20kDa, consistent with the model that Mvb12 requires Vps37 toassociate with ESCRT-I (Figure 3A, gel 5). The deletion of VPS23resulted in lower but detectable protein levels of Vps37-HAand Mvb12-HA. Analysis of this mutant strain by gel filtrationindicated that the remaining pool Vps37-HA and Mvb12-HA forma complex of $~$ 195 kDa in absence of Vps23 (Figure 3A, gel 7,and D). Our result does not exclude the possibility that this195-kDa complex contains Vps28. However, the crystal structureanalysis of ESCRT-I has shown that Vps23 acts as a linker betweenVps28 and Vps37, which argues against the presence of Vps28in 195-kDa complex (Kostelansky et al., 2006

; Teo et al., 2006

).Together, the results suggested that Vps37 and Mvb12 form asubcomplex.

Further support for the Vps37–Mvb12 interaction was obtainedby fluorescence microscopy. To visualize the low levels of Mvb12in different ESCRT-I mutants, we transformed the mutant strainswith a high-copy 2µ plasmid containing MVB12-GFP (Figure 4).In cells deleted for VPS4 the increased levels of Mvb12-GFPlocalized to class E compartments (Figure 4, arrows) similarto the localization found for Mvb12-GFP expressed at normallevels (Figure 1A). Previous studies have shown that the localizationof ESCRT-I to MVBs is mediated by the interaction of Vps23 withVps27 (Bache et al., 2003; Katzmann et al., 2003). As expectedfrom these studies we found that Mvb12 required Vps23 for properlocalization to the endosome (Figure 4, vps4 ${Delta}$ vps23 ${Delta}$ ). The deletionof VPS28 did not change the endosomal localization of Mvb12-GFP,indicating that Vps28 is not essential for membrane associationof Mvb12 (Figure 4, vps4 ${Delta}$ vps28 ${Delta}$ ). In contrast, loss of Vps37 resultedin the redistribution of Mvb12-GFP to the cytoplasm, consistentwith our model that Mvb12 binds via Vps37 to ESCRT-I (Figure 4,vps4 ${Delta}$ vps37 ${Delta}$ ).

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Figure 4. Mvb12 requires Vps23 and Vps37 to localize to endosomes. Fluorescent microscopy of Mvb12-GFP overexpressed from a high-copy plasmid in different mutant backgrounds (arrows indicate class E compartments).

Mvb12 Is an Unstable ESCRT-I Subunit
We determined the stability of Mvb12-HA in wild-type cells usingthe translational inhibitor cycloheximide. Cycloheximide wasadded to yeast cultures and samples were taken immediately (t= 0) and at 1, 2, and 3 h (t = 1 h, 2 h, and 3 h). The cellextracts were analyzed for the presence of Mvb12-HA, Vps23,and Vps37-HA by Western blot (Figure 5). In wild-type cells,Mvb12-HA was rapidly degraded with a half-life of <1 h. Vps37-HAwas more stable, having a half-life of 2 to 3 h. In contrast,the amount of Vps23 only changed marginally over the time periodof 3 h. Together, the data suggested that compared with othersubunits of ESCRT-I, Mvb12 is relatively unstable.

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Figure 5. Rapid turnover of Mvb12 by the proteasome depends on a functional MVB pathway. The translation inhibitor cycloheximide (50 mg/l) was added to yeast cultures (t = 0), and samples were taken after addition of the drug at the indicated time points. Cells were lysed using glass beads, and the resulting extracts were analyzed by Western blot for the presence of Vps23, Mvb12-HA, and Vps37-HA.

To determine which pathway is responsible for the degradationof Mvb12, we tested the stability of Mvb12-HA in the proteasomalmutant strain cim3-1 and a strain deleted for two major vacuolarpeptidases Pep4 and Prb1. These experiments demonstrated thatMvb12-HA is a stable protein in the proteasomal mutant, butonly a minor Mvb12-HA stabilization is observed in the straindeleted for vacuolar peptidases (Figure 5), indicating thatthe rapid degradation of Mvb12 is primarily dependent on theproteasomal system rather than the vacuole. This result is consistentwith the observations by fluorescence microscopy that showedno detectable levels of Mvb12-GFP in the vacuolar lumen (Figure 1A).

The rapid turnover of Mvb12 suggested that ESCRT-I repeatedlyexchanges the Mvb12 subunit with a newly synthesized copy. Thereforewe expected that blocking translation should result in a shiftin size of ESCRT-I over time from 350 to $~$ 170 kDa, the size ofESCRT-I in mvb12 ${Delta}$ . To test this prediction, we prepared a cellextract of a wild-type strain expressing Mvb12-HA after 2 hof cycloheximide treatment and analyzed this extract by gelfiltration. The Western blot in Figure 3C illustrates that thesample loaded onto the gel filtration column contained at leastfivefold less Mvb12-HA than the nontreated sample. In contrast,the amount of Vps23 remained stable during this procedure. Theresult of the gel filtration analysis indicated that duringthe cycloheximide treatment a large portion of ESCRT-I shiftedto a smaller molecular mass (Figure 3A, gel 8, and B, gel 12).Vps23 showed a very broad size distribution (170–350 kDa),which is consistent with a mixture of complete ESCRT-I and ESCRT-Imissing Mvb12 (Figure 3B). The remaining pool of Mvb12-HA shiftedto $~$ 260 kDa after blocking translation for 2 h (Figure 3A, gel9). It is expected that Mvb12-HA is only present in the largerforms of ESCRT-I that still contain this subunit. However, thatMvb12-HA shifts in size at all suggests that there is more thanone subunit of Mvb12 present in each 350-kDa ESCRT-I complex.

The data so far indicated that the ESCRT-I subunit Mvb12 isdegraded by the ubiquitin-proteasomal system and that the rateof degradation is faster than observed for other subunits ofthe ESCRT-I complex. The question remained whether the degradationof Mvb12 is connected to the function of ESCRT-I. Therefore,we analyzed the stability of Mvb12-HA in mutants that impaireither the recruitment of ESCRT-I to MVBs (vps27 ${Delta}$ ) or the dissociationof ESCRT-I from the endosomal membrane (vps4 ${Delta}$ ). The result shownin Figure 5 indicated that both type of mutants resulted instabilization of Mvb12-HA, suggesting that the instability ofMvb12 is a function of the transient localization of ESCRT-Ito MVBs.

Mvb12 Is Required for Efficient MVB Sorting
To study potential MVB trafficking defects, we transformed theMVB12 deletion strain with plasmids containing GFP-gene fusionsencoding for either CPS fused to GFP (GFP-CPS), Sna3-GFP, Ste2-GFP,or Ste3-GFP. Newly synthesized CPS and Sna3 are transmembraneproteins that are transported through the secretory pathwayand via MVBs to the lumen of the vacuole. In contrast to CPS,the sorting of Sna3 into the MVB pathway seems to be independentof ubiquitination (Odorizzi et al., 1998; Katzmann et al., 2001;Reggiori and Pelham, 2001; Yeo et al., 2003). Ste2 and Ste3are surface receptors that are endocytosed and delivered viathe MVB pathway to the vacuolar lumen (Odorizzi et al., 1998;Chen and Davis, 2002; Shaw et al., 2003). Therefore, in wild-typecells the GFP fluorescence of GFP-CPS and Ste2-GFP is observedby microscopy in the lumen of the vacuole (Figure 6A and SupplementalFigure 2). In contrast, cells defective in the MVB pathway,such as the ESCRT-I mutant vps23 ${Delta}$ , accumulate GFP-CPS, Sna3-GFP,Ste2-GFP, and Ste3-GFP in aberrant endosomes (class E compartments;Figure 6A, arrows, and Supplemental Figure 2) and mislocalizecargo proteins to the vacuolar membrane (Figure 6A and SupplementalFigure 2). Surprisingly, the analysis of the mvb12 ${Delta}$ traffickingphenotype indicated that these mutant cells have a less severedefect in the MVB sorting pathway (Figure 6A and SupplementalFigure 2). Unlike in vps23 ${Delta}$ , vps28 ${Delta}$ , and vps37 ${Delta}$ , in MVB12 deletionmutant cells GFP-CPS and Sna3-GFP do not accumulate in classE compartments, and a portion of GFP-CPS and Sna3-GFP is properlylocalized to the vacuolar lumen. Ste2-GFP and Ste3-GFP showedalmost normal trafficking in mvb12 ${Delta}$ with only a slight accumulationof the cargo in late endosomes. These data might suggest thatthe deletion of MVB12 affects the MVB trafficking of biosyntheticcargo more severely then the trafficking of cargo from the endocyticpathway.

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Figure 6. The deletion of MVB12 results in a mild MVB trafficking phenotype. (A) Strains expressing either GFP-CPS (pGO45) or Ste2-GFP (pCS24) were analyzed by fluorescence microscopy. White arrows indicate class E compartments. ESCRT-II was overexpressed by transforming the cells with the high-copy plasmid pMB175 (2µ ESCRT-II). (B) Invertase plate assay of wild type (BHY10), vps23 ${Delta}$ (EEY5-2), and mvb12 ${Delta}$ (MCY9).

A hallmark of class E vps mutants is a partial secretion ofvacuolar enzymes caused by the inefficient recycling of thesorting receptor Vps10 (Raymond et al., 1992

; Cereghino et al.,1995

; Cooper and Stevens, 1996

). This secretion phenotype canbe visualized using the reporter carboxypeptidase Y (CPY)-Invertasecombined with a colorimetric plate assay (Paravicini et al.,1992

). Wild-type cells efficiently sort CPY-Invertase to thevacuole and therefore remain white on the assay plate (Figure 6B).Class E vps mutants, such as vps23 ${Delta}$ , secrete CPY-Invertase, whichresults in the colorimetric reaction. In contrast, the MVB12deletion strain remained white, indicating that CPY-Invertasewas trafficked efficiently to the vacuole in this mutant strain(Figure 6B). Together, the trafficking studies indicated thatMvb12 is not an essential factor for MVB sorting; thus, unlikethe other ESCRT-I subunits, Mvb12 does not belong to the groupof class E Vps proteins. However, Mvb12 is necessary for theefficient transport of cargo proteins to the lumen of the vacuole.

One possible explanation for the partial MVB trafficking phenotypeis that Mvb12 function might be redundant. Therefore, we testedwhether overexpression of the ESCRT-I genes VPS23, VPS28, andVPS37 could suppress the GFP-CPS trafficking phenotype of anmvb12 ${Delta}$ strain. The data of these studies showed no suppressionof the GFP-CPS mislocalization (data not shown), suggestingthat high levels of the remaining ESCRT-I complex cannot replacethe function of Mvb12. However, in similar studies we foundthat overexpression of the ESCRT-II genes fully suppressed alltested trafficking defects in the mvb12 ${Delta}$ mutant (Figure 6A andSupplemental Figure 2). This result is consistent with previousstudies that showed suppression of ESCRT-I mutant phenotypesby overexpression of ESCRT-II (Katzmann et al., 2001) and thereforeis further support of the idea that Mvb12 functions as partof ESCRT-I. However, in contrast to the complete rescue of themvb12 ${Delta}$ phenotype, the mutant phenotype of other ESCRT-I subunitsis only partially suppressed by ESCRT-II overexpression (Katzmannet al., 2001).

Deletion of MVB12 Affects the Dissociation of ESCRT-I from MVBs
Our studies have shown that deletion of MVB12 results in theformation of a stable $~$ 170-kDa ESCRT-I complex that is at leastpartially able to function in the sorting of MVB cargo. To determinewhether lack of Mvb12 effects the transient association of ESCRT-Iwith the endosomal membrane, we studied the localization ofthe ESCRT-I subunit Vps23 in different strain backgrounds byusing a chromosomally integrated functional GFP-tagged VPS23fusion protein (Katzmann et al., 2001). As shown previously,Vps23-GFP localizes to the cytoplasm and endosomal compartmentsin wild-type cells and accumulates on class E compartments incells deleted for VPS4 (Figure 7A). Interestingly, we foundthat deleting MVB12 caused a portion of Vps23-GFP to be transportedinto the vacuolar lumen (Figure 7A). This transport requiredthe MVB trafficking pathway because the deletion of VPS4 inmvb12 ${Delta}$ prevented the vacuolar localization of Vps23-GFP and resultedin endosomal accumulation of the fusion protein similar as observedin the vps4 ${Delta}$ strain. Deletion of MVB12 did not effect Vps36-GFPlocalization (Figure 7A) but caused GFP-Vps27 to accumulateon large structures adjacent to the vacuole that most likelyare late endosomal compartments (Figure 7A). No accumulationof GFP-Vps27 was observed inside the vacuole. Similar redistributionof Vps27 has been observed in other ESCRT-I mutants (Katzmannet al., 2003). Interestingly, a mutation in the UEV domain ofVps23 (methionine 85 to threonine, M85T) that previously hadbeen shown to impair ubiquitin binding (Katzmann et al., 2001)resulted in loss of vacuolar localization of Vps23-GFP in mvb12 ${Delta}$ cells (Figure 7A). Because these cells expressed wild-type Vps23in addition to Vps23(M85T)-GFP, the observed effect was notdue to a defect in MVB trafficking. Together, these resultssuggest that binding to ubiquitinated cargo is necessary forthe delivery of Vps23-GFP into the vacuolar lumen of mvb12 ${Delta}$ cells.

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Figure 7. In mvb12 ${Delta}$ , ESCRT-I is mislocalized to the vacuolar lumen. (A) Fluorescence microscopy of strains expressing plasmid encoded GFP-VPS27 (pEE27-4) and VPS23(M85T)-GFP (pMB319) or chromosomally integrated VPS23-GFP and VPS36-GFP. Arrows indicate class E compartments. (B) Western blot analysis using a GFP-specific antibody of extracts from cells expressing chromosomally encoded Vps23-GFP (WT, DKY54; mvb12 ${Delta}$ , MBY73; 2µ ESCRT-II, pMB175).

We have shown that overexpression of ESCRT-II suppresses thetrafficking defect of an MVB12 deletion (Figure 6A). In contrast,we found that overexpression of ESCRT-II does not suppress thevacuolar localization of Vps23-GFP, but instead increases theseverity of this mislocalization phenotype (Figure 7A). Thisresult suggested that the increased efficiency of MVB sortingin the ESCRT-II overexpression strain also results in an increaseddelivery of ESCRT-I to the vacuolar lumen. The findings of thesemicroscopy studies are further supported by anti-GFP Westernblot analysis of extracts from wild-type, mvb12 ${Delta}$ -, and mvb12 ${Delta}$ -overexpressingESCRT-II cells, each containing the chromosomally integratedVPS23-GFP fusion (Figure 7B). In comparison with wild type cells,mvb12 ${Delta}$ cells contained an increased amount of truncated Vps23-GFP,which was even further increased when ESCRT-II was overexpressed.This increase in truncated Vps23-GFP mirrors the increased GFPsignal observed by microscopy in the lumen of the vacuole, suggestingthat the truncated Vps23-GFP species represent degradation intermediatesof vacuolar Vps23-GFP. As expected, the most prevalent degradationproducts are in the size range of GFP protein, which is generallya very stable protein ( $~$ 25 kDa). Furthermore, Western blot analysisshowed that the amount of full-length Vps23-GFP did not changedramatically in cells deleted for MVB12, suggesting that thedelivery of Vps23-GFP to the vacuole is inefficient and doesnot result in the depletion of cytoplasmic Vps23-GFP (Figure 7B).Because GFP is a very stable protein that is able to persistin the vacuole for an extended time period, the strong GFP signalobserved by microscopy in the vacuolar lumen of mvb12 ${Delta}$ expressingVps23-GFP (Figure 7A) is probably due to GFP accumulation overa long period rather than rapid vacuolar delivery of Vps23-GFP.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The ESCRT-I protein complex is part of the protein machinerythat executes endosomal (MVB) sorting of ubiquitinated cargoand formation of MVB vesicles (for review, see Hurley and Emr,2006). ESCRT-I localizes to the cytoplasm and is transientlyrecruited to the endosomal membrane. This recruitment step ismediated by the interaction of ESCRT-I with endosomal localizedVps27 (Bilodeau et al., 2003; Katzmann et al., 2003). On theendosome, ESCRT-I and Vps27 bind to monoubiquitinated cargoto initiate their sorting into MVB vesicles (Katzmann et al.,2001; Bilodeau et al., 2002). Subsequently, ESCRT-I interactswith ESCRT-II, a protein complex that functions in the formationof ESCRT-III (Babst et al., 2002a,b; Teo et al., 2006). Finally,ESCRT-I is released from the MVB membrane and recycled for furtherrounds of sorting.

In this study, we have found evidence for the presence of aforth subunit of yeast ESCRT-I, called Mvb12 (SGD: YGR206w).Immunoprecipitation and affinity purification experiments demonstrateda physical interaction between Mvb12 and ESCRT-I. Gel filtrationanalysis of yeast cell extract indicate that Mvb12 has a nativemolecular mass similar to that of ESCRT-I (350 kDa) and thatdeletion of MVB12 causes a shift in size of ESCRT-I from 350to $~$ 170 kDa. Furthermore, we observed that Mvb12 is unstablein cells lacking any of the ESCRT-I subunits. Finally, Mvb12colocalizes with ESCRT-I and the subcellular distribution ofMvb12 is consistent with the published transient MVB associationof ESCRT-I (Katzmann et al., 2001). Previous studies have shownthat native ESCRT-I has an apparent molecular mass of 350 kDaand is composed of the class E Vps proteins Vps23, Vps28, andVps37 (Babst et al., 2000; Katzmann et al., 2001). Recent crystalstructure analysis suggested that these three subunits forma trimeric complex with a 1:1:1 stoichiometry (Kostelansky etal., 2006; Teo et al., 2006). Because only a substructure ofESCRT-I has been analyzed by crystallography, the exact compositionof the in vivo observed 350-kDa complex remains unknown.

The gel filtration data of different ESCRT-I mutants are consistentwith a model in which Mvb12 interacts with ESCRT-I via the Vps37subunit. However, the number of Mvb12 subunits present in each350-kDa ESCRT-I complex is not clear. Deletion of MVB12 resultedin a shift in size of ESCRT-I from $~$ 350 to $~$ 170 kDa, suggestingthat Mvb12 might promote dimerization of a Vps23-Vps28-Vps37complex or that ESCRT-I contains at least 10 Mvb12 subunits.Finally, we cannot exclude the possibility that ESCRT-I containsadditional not yet identified subunits that require Mvb12 tointeract with ESCRT-I.

Both gel filtration analysis and immunoprecipitation experimentsindicate that Mvb12 is tightly associated with ESCRT-I. Surprisingly,in wild-type cells we observed a rapid proteasome-dependentturnover of Mvb12, resulting in a half-life of Mvb12 that ismuch shorter then the half-life of other ESCRT-I subunits. Asa consequence, when new protein synthesis was blocked, the ESCRT-Icomplex gradually shifted in size from $~$ 350 to $~$ 170 kDa. Thisresult indicated that during the lifetime of an ESCRT-I complex,Mvb12 is repeatedly degraded and replaced by newly synthesizedMvb12 subunits. Interestingly, Mvb12 degradation was found tobe dependent on the transient localization of ESCRT-I to theendosome. Loss of either the ESCRT-I recruiting factor Vps27or the recycling factor Vps4 resulted in the stabilization ofMvb12. This result suggested that the rapid degradation of Mvb12is a consequence of ESCRT-I function on the endosome.

Loss of function of Vps23, Vps28, or Vps37 resulted in a completeblock of the MVB pathway (Babst et al., 2000; Katzmann et al.,2001). In contrast, deletion of MVB12 only partially affectsthe transport of MVB cargoes to the vacuolar lumen, indicatingthat Mvb12 is not an essential factor for ESCRT-I function.We found that the trafficking defects in mvb12 ${Delta}$ are more severefor cargo of the biosynthetic pathway (e.g., CPS and Sna3) thanfor endocytic cargo (e.g., Ste2 and Ste3). It is not clear whetherthis difference indicates the presence of two partially separateMVB pathways, a biosynthetic and an endocytic pathway, or whetherit reflects cargo specificity of Mvb12 function.

In mvb12 ${Delta}$ cells, ESCRT-I localizes to endosomal compartmentsand the lumen of the vacuole, indicating that Mvb12 is not requiredfor the recruitment of ESCRT-I to MVBs but instead seems tobe play a role in the dissociation of ESCRT-I from the endosomeafter the function of ESCRT-I in cargo sorting is completed.However, the delivery of ESCRT-I into the MVB pathway in MVB12-deletedcells is not efficient enough to deplete the cells of ESCRT-Iand is not the cause of the MVB-trafficking defects observedin mvb12 ${Delta}$ . Consistent with the role of ESCRT-II in cargo sortingdownstream of ESCRT-I, we found that overexpression of ESCRT-IIsuppressed the trafficking phenotype of mvb12 ${Delta}$ . In contrast,the mislocalization of mutant ESCRT-I to the vacuolar lumenwas enhanced by the overexpression of ESCRT-II, suggesting thatESCRT-II overexpression increased MVB trafficking not only ofcargo but also of ESCRT-I.

Deletion of MVB12 caused ESCRT-I to be targeted to the vacuolarlumen, but it did not result in vacuolar localization of Vps27or ESCRT-II. This observation suggests that the defect in ESCRT-Irecycling in mvb12 ${Delta}$ is not a result of ESCRT-I not being ableto break the interactions with other ESCRT machinery, but ratherit is caused by maintaining (prolonging) the interaction withubiquitinated cargo. This model is supported by the observationthat a ubiquitin-binding mutant of Vps23 does not get deliveredto the vacuolar lumen in an MVB12 deletion strain. Several proteinsof the ESCRT machinery contain ubiquitin-binding domains thatrecognize a similar ubiquitin surface (for review, see Hurleyand Emr, 2006). It has therefore been speculated that ubiquitinatedcargo might be handed over from one ubiquitin-binding proteincomplex to the next (e.g., from ESCRT-I to ESCRT-II). However,the mvb12 ${Delta}$ phenotype suggests that cargo is sorted into the MVBpathway even when it remains bound to ESCRT-I. Furthermore,we observed that overexpression of ESCRT-II in mvb12 ${Delta}$ resultsin increased transport of both cargo and ESCRT-I to the vacuolarlumen, indicating that ESCRT-II does not compete with ESCRT-Ifor cargo. Together, our data are most consistent with a modelin which sorting of ESCRT-I-bound cargo into MVB vesicles doesnot require the release of cargo from ESCRT-I and subsequentinteraction with ESCRT-II.

Although Mvb12 plays an important role in the function of yeastESCRT-I, the protein sequence of Mvb12 is evolutionarily poorlyconserved. As a consequence, convincing Mvb12 homologues areonly found among other fungal species. However, lack of sequencehomology does not rule out the possibility that functional homologuesof Mvb12 also exist in higher eukaryotes. Similar to Mvb12,very little sequence conservation is observed between Vps37proteins from different species. Considering the high structuraland functional conservation of other parts of the ESCRT machineryit is unlikely that this sequence diversity among differentspecies reflects a difference in the function of ESCRT-I.

The current MVB sorting model suggests that after recruitmentto the MVB, ESCRT-I binds to ubiquitinated cargo and to ESCRT-II,which initiates the formation of ESCRT-III. At some point, eitherduring ESCRT-III formation or the dissociation of ESCRT-IIIby Vps4, the ESCRT-I complex dissociates from the ESCRT machineryand is released to the cytoplasm for further rounds of sorting.Our data suggest that loss of Mvb12 affects a step in ESCRT-Ifunction after the endosomal recruitment and binding of cargo.This defect results in inefficient cargo sorting and in inefficientdissociation of ESCRT-I from the MVB. One possible functionfor Mvb12 could be to interact with other components of theESCRT machinery, thereby regulating and coordinating the transientinteractions of ESCRT-I with cargo and machinery. Without Mvb12,ESCRT-I might not properly activate the downstream ESCRT-IIcomplex, which might affect the release of ESCRT-I from theubiquitinated cargo. The rapid degradation of Mvb12 observedin wild-type cells might be a result of the ESCRT-I releasefrom the MVB. During the release reaction, Mvb12 might dissociatefrom the complex and be degraded by the proteasomal system.It will be interesting to test whether the observed modificationof endosomal Mvb12 plays a role in regulating the interactionbetween ESCRT-I, ubiquitinated cargo, and other parts of theESCRT machinery.

ACKNOWLEDGMENTS

We thank Tamara Darsow for critical reading of the manuscript.We thank Dan Gottschling for providing the cim3-1 strain. Thiswork has been supported by grant R01 GM-074171-01 A1 from theNational Institute of Health and by a Funding Incentive SeedGrant (project 51003083) from the University of Utah.

Footnotes

The online version of this contains supplemental material at MBC Online (http://www.molbiolcell.org).

This article was published online ahead of print in MBC in Press(http://www.molbiolcell.org/cgi/doi/10.1091/mbc.E06-07-0588)on November 29, 2006.

Address correspondence to: Markus Babst (babst{at}biology.utah.edu)

Abbreviations used: ESCRT, endosomal sorting complex required for transport; MVB, multivesicular body; Vps, vacuolar protein sorting.

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TOP
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DISCUSSION
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