Constitutive Activation of the pH-Responsive Rim101 Pathway in Yeast Mutants Defective in Late Steps of the MVB/ESCRT Pathway

In many fungi, transcriptional responses to alkaline pH aremediated by conserved signal transduction machinery. In thehomologous system in Saccharomyces cerevisiae, the zinc-fingertranscription factor Rim101 is activated under alkaline conditionsto regulate transcription of target genes. The activation ofRim101 is exerted through proteolytic processing of its C-terminalinhibitory domain. Regulated processing of Rim101 requires severalproteins, including the calpain-like protease Rim13/Cpl1, aputative protease scaffold Rim20, putative transmembrane proteinsRim9, and Rim21/Pal2, and Rim8/Pal3 of unknown biochemical function.To identify new regulatory components and thereby determinethe order of action among the components in the pathway, wescreened for suppressors of rim9 ${Delta}$ and rim21 ${Delta}$ mutations. Threeidentified suppressors—did4/vps2, vps24, and vps4—allbelonged to "class E" vps mutants, which are commonly defectivein multivesicular body sorting. These mutations suppress rim8,rim9, and rim21 but not rim13 or rim20, indicating that Rim8,Rim9, and Rim21 act upstream of Rim13 and Rim20 in the pathway.Disruption of DID4, VPS24, or VPS4, by itself, uncouples pHsensing from Rim101 processing, leading to constitutive Rim101activation. Based on extensive epistasis analysis between pathway-activatingand -inactivating mutations, a model for architecture and regulationof the Rim101 pathway is proposed.

INTRODUCTION

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Introduction

Microorganisms must regulate gene expression to cope with changesin environmental pH. In many fungi, transcriptional responsesto alkaline pH are mediated by conserved signal transductionmachinery (59). Extensive studies conducted on the prototypicalpathway of Aspergillus nidulans have led to many of our currentinsights into the molecular machinery of homologous pathways(3, 59). In the A. nidulans pathway, the zinc-finger transcriptionfactor PacC, is activated at alkaline pH to directly regulatetranscription of pH-responsive genes (17, 72). Activation ofPacC is exerted through proteolytic processing and removal ofits C-terminal inhibitory domain at alkaline pH (21, 50, 55).The processing of PacC requires several proteins called thePal proteins, whose deficiency causes acidity-mimicking phenotypes(2, 17, 19, 20, 48, 53, 54, 55). A set of dominant mutants ofpacC that encode C-terminally truncated proteins mimicking theprocessed form behave as constitutively active mutants (pacC^C)and cause alkalinity-mimicking phenotypes (17, 55, 72). Becausethe acidity-mimicking phenotypes of any of the pal mutants aresuppressed by pacC^C, the Pal proteins are concluded to constitutea pathway that regulates processing of PacC in response to alkalinepH (2, 17). However, the absence of other alkalinity-mimickingmutants has hindered similar genetic analyses meant to determinethe order of action among the Pal proteins in the pathway.

In Saccharomyces cerevisiae, the homologous pathway regulatesproteolytic processing of Rim101, which is the ortholog of PacC(59). Rim101 was originally identified as a positive regulatorfor meiotic gene expression (also referred to as Rim1 [68, 69])and was subsequently shown to be responsible for alkaline pH-responsivegene expression and thereby for adaptation to alkaline conditions(25, 40, 41, 65). Rim101 also is activated by C-terminal proteolyticprocessing that is stimulated at alkaline pH (44). Several proteinshomologous to the Pal proteins in A. nidulans are required forthis processing, including the calpain-like protease Rim13/Cpl1,a putative protease scaffold Rim20, putative transmembrane proteinsRim9 and Rim21/Pal2, and Rim8/Pal3, a protein of unknown biochemicalfunction (25, 41, 44, 73, 79). Defective mutants in any of theseRim proteins show sensitivity to alkaline conditions, as wellas LiCl-containing medium. The latter phenotype is caused byreduced expression of ENA1, encoding the cation extrusion pump,whose efficient expression is dependent on Rim101 processing(41). Recently, Rim101 was shown to function as a transcriptionalrepressor that negatively regulates expression of several targetgenes, including NRG1 and SMP1; the product of the former isin turn required for repression of ENA1 (40). Like A. nidulansPacC^C, C-terminally truncated mutants of Rim101 that mimic theprocessed form, such as Rim101 ${Delta}$ C531, also behave as constitutivelyactive forms and negate the requirement for Rim13 activity oractivity of any ofthe other Rim proteins needed for Rim101 processing(25, 44; E. Futai and T. Maeda, unpublished data). Therefore,molecular machinery homologous to what operates in A. nidulansappears to regulate Rim101 processing in S. cerevisiae (hereafterreferred to as the "Rim101 pathway"). The mechanism by whichthe pathway executes regulated processing of Rim101, however,is not known, for the primary structures of the constituentcomponents, with the exception of the calpain-like proteaseRim13, whose proteolytic activity is essential for the pathway(25), provide little insight into their biochemical functions.Further, phenotypes of mutants defective in these componentsare indistinguishable from one another. The order of actionamong the Rim proteins in the pathway has also been difficultto determine, as is the case for the A. nidulans pathway. Homologouspathways are widely conserved among other fungal species, includingYarrowia lipolytica (27, 42, 73) and Candida albicans (18, 43,61, 62).

Recently, machinery for vacuolar protein sorting was implicatedin activation of the Rim101 pathway. Vacuolar sorting is mediatedby the concerted action of a set of proteins collectively calledvacuolar protein sorting (VPS) gene products (31). Among proteinsdestined for the vacuole, a membrane-bound precursor of carboxypeptidaseS (CPS), as well as endocytosed cell surface receptors and transportersdestined for vacuolar degradation, are recognized at the endosomeand are sorted into multivesicular bodies (MVBs), endosomalstructures formed by the invagination and budding of the limitingmembrane into the lumen of the compartment (34). After fusionof the MVB with the vacuole, the lumenal vesicles with theircargo proteins are exposed to vacuolar hydrolases for degradation.Sorting of these cargo proteins and formation of the MVB requirea group of VPS gene products categorized as "class E," whichinclude all components of three protein complexes called ESCRTs(for endosomal sorting complex required for transport): ESCRT-I,-II, and -III. Null mutations in any of the "class E" VPS genescommonly result in defective MVB sorting and accumulation ofa malformed endosomal structure called the "class E" compartment.As a signal for MVB sorting, many cargo proteins, such as theprecursor of CPS and cell surface receptors, are ubiquitinatedwithin cytoplasmically exposed domains. Among the "class E"Vps proteins, the Stp22/Vps23 subunit of the ESCRT-I complex(composed of Stp22, Vps28, and Srn2/Vps37) and Vps27 bind toubiquitin and thus select ubiquitinated cargo proteins for transport(7, 29, 33, 45, 60, 63, 67). Vps27 also binds the endosomallyenriched lipid species phosphatidylinositol 3- phosphate andthereby initiates MVB sorting on the endosomal membrane (15,35). ESCRT-I is then recruited for MVB sorting through directinteraction with Vps27 and binds to ubiquitinated cargo proteins(35). ESCRT-I then recruits ESCRT-II (composed of Snf8/Vps22,Vps25, and Vps36) onto the endosomal membrane, which in turninitiates assembly and recruitment of ESCRT-III onto the endosomalmembrane (6, 47, 82). ESCRT-III is composed of the soluble coiled-coil-containingproteins Did4/Vps2, Vps20, Vps24, and Snf7/Vps32, which arerecruited from the cytoplasm to the endosomal membrane, wherethey oligomerize into the complex (1, 5, 9, 37, 74). ESCRT-IIIcontains two functionally distinct subcomplexes (5). The Vps20-Snf7subcomplex binds to the endosomal membrane, in part throughthe myristoyl group of Vps20 (5). The Did4-Vps24 subcomplexbinds to the Vps20-Snf7 subcomplex and thereby serves to recruitadditional cofactors to the site of protein sorting, such asVps4, which is an AAA-type ATPase catalyzing dissociation anddisassembly of all three ESCRT complexes from the endosomalmembrane after sorting is complete, and Doa4, which catalyzesthe deubiquitination of cargo proteins to recycle ubiquitin(1, 5, 8, 56). The ESCRT complexes are thus proposed to performa coordinated cascade of reactions that direct selection andsorting of MVB cargo proteins destined for delivery to the lumenof the vacuole.

A possible link between the Rim101 pathway and MVB sorting wassuggested by several observations. For example, in a study ofalkaline adaptation in Y. lipolytica, vps28, together with rimhomolog mutants, was identified as a mutant in which inductionof pH-responsive reporter genes was eliminated, although Rim101processing in vps28 cells was not examined (27). In addition,a genome-wide protein interaction analysis suggested that Rim20interacts with Snf7, and Snf7 in turn interacts with Rim13 (30,79). Recently, Xu et al. reported that Rim101 processing isdeficient in stp22 ${Delta}$ , vps28 ${Delta}$ , srn2 ${Delta}$ , snf8 ${Delta}$ , vps25 ${Delta}$ , vps36 ${Delta}$ , snf7 ${Delta}$ , andvps20 ${Delta}$ mutants but proficient in other "class E" vps mutants(80). Also in C. albicans, snf7 ${Delta}$ mutants are defective in Rim101processing and show phenotypes attributed by the defect (39).

Here we screened for suppressors of two mutations, rim9 ${Delta}$ andrim21 ${Delta}$ , that cause deficiency in putative membrane-associatedcomponents of the Rim101 pathway. The three identified suppressorswere all found to belong to "class E" vps mutations. These mutationscause constitutive activation of the Rim101 pathway by themselves.Based on extensive epistasis analysis between these pathway-activatingmutations and pathway-inactivating rim and vps mutations, amodel for the architecture of the Rim101 pathway and its regulationis proposed.

MATERIALS AND METHODS

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Materials and Methods

Molecular genetic methods. Standard Escherichia coli and yeast manipulations were performedas described previously (4). E. coli strain XL10-Gold (Stratagene,San Diego, CA) was used for plasmid propagation.

Yeast media. Yeast extract-peptone-dextrose (YPD), synthetic dextrose (SD),synthetic complete (SC) dropout, and sporulation media wereprepared as described previously (16). SD was supplemented withappropriate auxotrophic requirements. SD and SC were bufferedwhere noted in Results with 50 mM morpholinepropanesulfonicacid and 50 mM morpholineethanesulfonic acid and adjusted topH 3.5 or 4 with HCl or to pH 5.5, pH 7, or pH 7.5 with NaOH.In order to clone the corresponding genes for the suppressors,SD was supplemented with 7.5 µM erythrosin B (12).

Yeast strains. Yeast strains are listed in Table 1. All strains used were derivedin the S288C background (14, 77) except for those used for screening(38). RIM101 in CH1305 and RIM9 or RIM21 in CH1462 were disruptedby replacement with a kanMX6 cassette amplified by PCR as describedpreviously (46) to generate FI1, FI3, and FI5, respectively.FI10-2d and FI10-5a were constructed by crossing FI1 with FI3.FI11-3c and FI11-13b were constructed by crossing FI1 with FI5.

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TABLE 1. Yeast strains

FM81, FM91, FM201, and FM301 were constructed by replacing RIM8,RIM9, RIM20, and RIM21 of TM141 with a HIS3 cassette amplifiedby PCR as described previously (14). DID4 in FM81, FM91, FM201,FM301, and MTM100 was disrupted by replacement with kanMX6 amplifiedby PCR. The resultant double disruptant strains were backcrossedwith TM225 to generate VB181-3a, VB191-11c, VB121-5d, VB131-1a,VB151-5d, and VB101-6b. VPS24 in TM141, FM81, FM91, FM201, FM301,and MTM100 was disrupted by replacement with kanMX6 amplifiedby PCR. The resultant double disruptant strains were backcrossedwith TM225 to generate VX101-10a, VX181-6a, VX191-6d, VX121-2c,VX131-5a, and VX151-1c. VPS4 in TM225 was disrupted by replacementwith kanMX6 amplified by PCR to generate FT11. FT101, FT181,FT191, FT121, FT131, and FT151 were constructed by crossingTM141, FM81, FM91, FM201, FM301, and MTM100 with FT11. SNF7,VPS20, and VPS24 in TM225 were disrupted by replacement withHis3MX6 amplified by PCR to generate SG11, VT11, and VX401,respectively. SG101-9b, VB271-26c, and VX271-13d were constructedby crossing VB101-6b and VX101-10a with SG11. VT101-6d, VB321-1a,and VX321-4d were constructed by crossing VB101-6b and VX101-10awith VT11. All gene disruptions constructed with kanMX6 or His3MX6cassettes were confirmed by Southern analyses.

The stp22 ${Delta}$ (strain 3416), vps28 ${Delta}$ (strain 2763), snf8 ${Delta}$ (strain 2826),vps25 ${Delta}$ (strain 2580), vps36 ${Delta}$ (strain 5325), and parental (strainBY4741) strains were obtained from Open Biosystems (Huntsville,AL) (14, 78). The authenticity of each disruptant was confirmedas follows. These mutant strains exhibited temperature-sensitivegrowth and LiCl-sensitive phenotypes (data not shown). Plasmidscontaining the corresponding wild-type alleles were cloned andfound to complement both phenotypes of the respective disruptants(data not shown). These results indicate that in each of abovestrains, the correct gene had been disrupted.

VV3-3c, VV3-9b, VV15-9c, VV15-4b, VV7-2c, VV7-10d, VV7-7b, VV11-14a,VV11-3a, VV19-10a, and VV19-16d were constructed by crossingstrains 3416, 2580, 2763, 2826, and 5325 with VX401.

Plasmids. pRIM101-2, an RIM101 plasmid with a NotI site introduced upstreamof the first codon, has been described (25). Oligonucleotidesencoding three tandem copies of the hemagglutinin (3x HA) epitopewere inserted into the NotI site. The resultant 3HA-RIM101 fragment(2.1 kb, BamHI-EcoRI) and an ADE3 fragment (3.7 kb, BamHI-NheI)were inserted into the BamHI-EcoRI sites and the XbaI site ofthe pRS415 polylinker, respectively, to construct pFI1.

pAS416 was obtained from a YCp50 yeast genomic library as aplasmid rescuing the slow-growth phenotype of a did4 mutant(A6). Formation of larger and whiter colonies on SD plates containingerythrosin B was used as rescue criteria. pAS416 was found toharbor a 3.8-kb insert containing DID4. A 2.5-kb HindIII fragmentcontaining DID4 and a portion of vector sequence was subclonedinto the HindIII site of YCp50 to generate pAS4163.

pAS31 was obtained from the YCp50 yeast genomic library as aplasmid rescuing the slow-growth of a vps24 mutant (A108-9a),as described for DID4. The plasmid was found to harbor a 5.1-kbinsert containing VPS24. A 1.7-kb ClaI fragment containing VPS24was subcloned into the ClaI site of YCp50 to generate pAS311.

A 1.1-kb HindIII fragment containing URA3 was inserted in pRS415with modified multiple cloning sites to obtain pTB554. Immediatelyupstream of the initiation codon of URA3 on pTB554, a 1.0-kbPCR product upstream of YPL277C containing its promoter wasinserted by homologous recombination to construct pAT003.

Screening for suppressors. FI10-2d, FI10-5a, FI11-3c, and FI11-13b transformed with pFI1were mutagenized with ethyl methanesulfonate as described previously(16) (viability 30 to 40%), diluted, plated on YPD plates containing0.16 or 0.21 M LiCl, and incubated for a week. Nonsectoring"red-only" colonies were selected and retested for the phenotypeby streaking onto YPD plates containing 0.21 M LiCl. Candidateclones were retested on the same plates after incubation onYPD plates for 1 day to promote plasmid loss. To exclude mutantsthat restored LiCl tolerance due to activating mutations inpFI1 plasmid-borne RIM101, the plasmid was cured from each mutantand, after retransformation with pFI1, mutants were retestedon the same plates. Finally, by Western blotting with an anti-HAantibody, mutants harboring processed HA-Rim101 were selected.

Detection of HA epitope-tagged Rim101. Cells transformed with pFI1 were precultured in SD, inoculatedin YPD at an optical density at 600 nm (OD₆₀₀) of ca. 0.4, andincubated for 4 h. Cells were collected, washed with 1 mM phenylmethylsulfonylfluoride (this extra washing step is only for the experimentsin Fig. 2A, 3A, and 4A), suspended in Laemmli sample buffer,and boiled for 5 min. Samples were then cooled on ice and vortexedwith glass beads for 30 s eight times with 30-s intervals onice. Cell lysates corresponding to OD of 0.5 were boiled for1 min and subjected to Western blotting with the anti-HA monoclonalantibody 12CA5 and IRDye-conjugated anti-mouse antibody (Rockland,Gilbertsville, PA). To detect actin for a loading control, theanti-actin monoclonal antibody C4 (ICN, Aurora, OH) was usedas a primary antibody. Signals were detected by using the infraredimaging system Odyssey (LI-COR, Lincoln, NE) according to themanufacturer's instructions. For the experiments in Fig. 2A,cells were precultured to late log phase (OD = 0.6 to 1) inSD at pH 5.5, inoculated in each buffered SD medium at an ODof 1, and harvested after 30 min. Sample preparation and Westernblotting were performed as described above.

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FIG. 2. did4 ${Delta}$ , vps24 ${Delta}$ , and vps4 ${Delta}$ mutations activate the Rim101 pathway constitutively. (A) Constitutive and pH-independent processing of Rim101 is observed in did4 ${Delta}$ , vps24 ${Delta}$ , and vps4 ${Delta}$ mutants. HA-Rim101 was expressed from pFI1 in wild-type (TM141), did4 ${Delta}$ (VB101-6b), vps24 ${Delta}$ (VX101-10a), vps4 ${Delta}$ (FT101), and rim9 ${Delta}$ (FM91) strains. Cells were grown to logarithmic phase in SD buffered at pH 5.5 and then transferred to SD buffered at pH 3.5, 5.5, or 7.5 for 30 min. Cell lysates were prepared, and processed and unprocessed forms of HA-Rim101 (indicated) were detected as described in the legend to Fig. 1. Actin Western blotting was used as a loading control. (B) Constitutive and pH-independent repression of the Rim101-repressible YPL277C promoter is observed in did4 ${Delta}$ , vps24 ${Delta}$ , and vps4 ${Delta}$ mutants. The P_YPL277C-URA3 reporter plasmid pAT003 (P_YPL-URA3) or pRS415 (vec) was introduced in the strains used in panel A. The transformants were streaked on SC-LU and SC-L plates adjusted to indicated pH and then incubated at 30°C for 3 days.

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FIG.3. did4 ${Delta}$ , vps24 ${Delta}$ , and vps4 ${Delta}$ mutations suppress rim8 ${Delta}$ , rim9 ${Delta}$ , and rim21 ${Delta}$ but not rim20 ${Delta}$ or rim13 ${Delta}$ . (A) did4 ${Delta}$ , vps24 ${Delta}$ , and vps4 ${Delta}$ mutations suppress defective Rim101 processing of rim8 ${Delta}$ , rim9 ${Delta}$ , and rim21 ${Delta}$ mutants but not that of rim20 ${Delta}$ and rim13 ${Delta}$ mutants. HA-tagged Rim101 was expressed from pFI1 in wild-type (TM141), rim8 ${Delta}$ (FM81), rim9 ${Delta}$ (FM91), rim20 ${Delta}$ (FM201), rim21 ${Delta}$ (FM301), and rim13 ${Delta}$ (MTM100) strains and their did4 ${Delta}$ (top panel), vps24 ${Delta}$ (middle panel), and vps4 ${Delta}$ (bottom panel) derivatives: did4 ${Delta}$ (VB101-6b), rim8 ${Delta}$ did4 ${Delta}$ (VB181-3a), rim9 ${Delta}$ did4 ${Delta}$ (VB191-11c), rim20 ${Delta}$ did4 ${Delta}$ (VB121-5d), rim21 ${Delta}$ did4 ${Delta}$ (VB131-1a), rim13 ${Delta}$ did4 ${Delta}$ (VB151-5d), vps24 ${Delta}$ (VX101-10a), rim8 ${Delta}$ vps24 ${Delta}$ (VX181-6a), rim9 ${Delta}$ vps24 ${Delta}$ (VX191-6d), rim20 ${Delta}$ vps24 ${Delta}$ (VX121-2c), rim21 ${Delta}$ vps24 ${Delta}$ (VX131-5a), rim13 ${Delta}$ vps24 ${Delta}$ (VX151-1c), vps4 ${Delta}$ (FT101), rim8 ${Delta}$ vps4 ${Delta}$ (FT181), rim9 ${Delta}$ vps4 ${Delta}$ (FT191), rim20 ${Delta}$ vps4 ${Delta}$ (FT121), rim21 ${Delta}$ vps4 ${Delta}$ (FT131), and rim13 ${Delta}$ vps4 ${Delta}$ (FT151) strains. Processed and unprocessed forms of HA-Rim101 (indicated) were detected as described in the legend to Fig. 1. Actin Western blotting was used as a loading control. +, intact; –, deleted. (B) did4 ${Delta}$ , vps24 ${Delta}$ , and vps4 ${Delta}$ mutations suppress the LiCl sensitivity of rim8 ${Delta}$ , rim9 ${Delta}$ , and rim21 ${Delta}$ mutants but do not suppress that of the rim20 ${Delta}$ or rim13 ${Delta}$ mutant. The strains used in panel A were streaked on YPD and YPD containing 0.32 M LiCl plates and incubated at 30°C for 5 (lower panel) or 6 (upper and middle panels) days.

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FIG. 4. Epistasis tests between the Rim101 pathway-inactivating ESCRT mutations and did4 or vps24. (A) Defective Rim101 processing of stp22 ${Delta}$ and vps28 ${Delta}$ mutants is suppressed by vps24 ${Delta}$ , that of an snf8 ${Delta}$ mutant is suppressed moderately, and that of vps25 ${Delta}$ and vps36 ${Delta}$ mutants is not suppressed by vps24 ${Delta}$ . HA-tagged Rim101 was expressed from pFI1 in wild-type (BY4741), stp22 ${Delta}$ (VV3-3c), vps28 ${Delta}$ (VV7-10d), snf8 ${Delta}$ (VV11-14a), vps25 ${Delta}$ (VV15-9c), and vps36 ${Delta}$ (VV19-10a) strains and their vps24 ${Delta}$ derivatives: vps24 ${Delta}$ (VV7-2c), stp22 ${Delta}$ vps24 ${Delta}$ (VV3-9b), vps28 ${Delta}$ vps24 ${Delta}$ (VV7-7b), snf8 ${Delta}$ vps24 ${Delta}$ (VV11-3a), vps25 ${Delta}$ vps24 ${Delta}$ (VV15-4b), and vps36 ${Delta}$ vps24 ${Delta}$ (VV19-16d) strains. Processed and unprocessed forms of HA-Rim101 (indicated) were detected as described in the legend to Fig. 1. (B) The LiCl sensitivity of stp22 ${Delta}$ and vps28 ${Delta}$ mutants is suppressed by vps24 ${Delta}$ , that of an snf8 ${Delta}$ mutant is suppressed moderately, and that of vps25 ${Delta}$ and vps36 ${Delta}$ mutants is not suppressed by vps24 ${Delta}$ . The strains used in panel A were streaked on YPD and YPD containing 0.32 M LiCl plates and incubated at 30°C for 6 days. (C) Defective Rim101 processing of snf7 ${Delta}$ and vps20 ${Delta}$ mutants is not suppressed by did4 ${Delta}$ or vps24 ${Delta}$ . HA-tagged Rim101 was expressed from pFI1 in wild-type (TM141), snf7 ${Delta}$ (SG101-9b), and vps20 ${Delta}$ (VT101-6d) strains and their did4 ${Delta}$ and vps24 ${Delta}$ derivatives: did4 ${Delta}$ (VB101-6b), vps24 ${Delta}$ (VX101-10a), snf7 ${Delta}$ did4 ${Delta}$ (VB271-26c), snf7 ${Delta}$ vps24 ${Delta}$ (VX271-13d), vps20 ${Delta}$ did4 ${Delta}$ (VB321-1a), and vps20 ${Delta}$ vps24 ${Delta}$ (VX321-4d), rim8 ${Delta}$ (FM81), rim9 ${Delta}$ (FM91), rim20 ${Delta}$ (FM201), rim21 ${Delta}$ (FM301), and rim13 ${Delta}$ (MTM100) strains. Processed and unprocessed forms of HA-Rim101 (indicated) were detected as described in the legend to Fig. 1. (D) The LiCl sensitivity of snf7 ${Delta}$ and vps20 ${Delta}$ mutants is not suppressed by did4 ${Delta}$ or vps24 ${Delta}$ . The indicated strains used in panel C were streaked on YPD and YPD containing 0.32 M LiCl plates and incubated at 30°C for 5 days.

RESULTS

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Results

Screening for suppressors of rim9 ${Delta}$ or rim21 ${Delta}$ . To identify new regulatory components in the Rim101 pathwayand thus determine the order of action among the componentsin the pathway, we conducted a screen for mutations that suppressedthe phenotypes of disruption alleles of RIM9 and RIM21. Rim9and Rim21 are putative membrane proteins and thus are more likelyto function upstream in the pathway (44, 73). Our initial attemptsto isolate suppressors of rim9 ${Delta}$ and rim21 ${Delta}$ were, however, impededby bypass suppressors. The screen for suppressors selected mutantswhose growth in the presence of LiCl was restored, althoughnone of the isolated mutants restored Rim101 processing (datanot shown). It is likely that in these mutants LiCl tolerancewas acquired through other mechanisms that also activate ENA1expression. To isolate Rim101 pathway-specific suppressors thatrestored LiCl tolerance through restoration of Rim101 processing,the original screen was redesigned.

For clarity, only the screen for rim9 ${Delta}$ suppressors is described.Parental strains were constructed by disrupting both RIM9 andRIM101 in a pair of ade2 ade3 host strains and then transformingthem with the screening plasmid pFI1, harboring HA-epitope-taggedRIM101 and ADE3, to facilitate a colony color assay (38). Theparental strains had the overall genotype of rim9 ${Delta}$ and were thereforesensitive to LiCl. Suppressors were then sought that restoredwild-type tolerance to LiCl from these parental strains. Amongthe mutants expected to be isolated, uninteresting bypass suppressorsthat restored LiCl tolerance independently of Rim101 processingwould not require the pFI1 plasmid for the suppression and thuswere expected to form white colonies or red colonies with manywhite sectors on plates containing LiCl. In contrast, the sought-afterRim101 pathway-specific suppressors would require pFI1 for thesuppression and therefore were expected to form nonsectoringred colonies on plates containing LiCl. In addition, the intendedpathway-specific suppressors were expected to permit formationof white or sectoring colonies on plates that did not containLiCl because pFI1 would not then be required. This feature wasused to exclude mutants that retained pFI1 for reasons otherthan a dependence on Rim101 for LiCl tolerance. Suppressorsthat restored LiCl tolerance due to activating mutations inpFI1-encoded Rim101, such as truncation of the C terminus, werethen excluded by retesting the LiCl tolerance of candidate mutantsafter once curing the screening plasmids from them and thenreintroducing genuine pFI1 by transformation. Finally, restorationof Rim101 processing was examined by Western analysis. Similarscreening was also performed for suppressors of rim21 ${Delta}$ .

Parental strains were mutagenized with ethyl methanesulfonatetreatment to a survival rate of 30 to 40%. Nineteen mutantswere obtained that harbored rim9 ${Delta}$ suppressors restoring bothLiCl tolerance and Rim101 processing among a total of 5.6 x10⁶ clones (Fig. 1A and B). All of the mutations were foundto be recessive and were classified into two complementationgroups: A and B consisting of 12 and 7 representatives, respectively.Mutants in both complementation groups commonly exhibited slowgrowth on SD plates and formed colonies that stained darkerred than parental strains on SD plates containing the red vitaldye, erythrosin B, which accumulates in dead cells (data notshown). Plasmids that restored growth on SD plates, and thatalso restored defective Rim101 processing were isolated froma wild-type genomic library constructed in YCp50. Subcloningof the isolated plasmids identified DID4/VPS2 (1) and VPS24(9) as the genes corresponding to group A and B mutants, respectively(Fig. 1B). Phenotypes of the double mutants constructed usingrim9 ${Delta}$ , and did4 ${Delta}$ or vps24 ${Delta}$ confirmed the conclusions (see below).

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FIG. 1. Screening for rim9 ${Delta}$ suppressors. (A) LiCl sensitivity caused by rim9 ${Delta}$ is suppressed by did4 and vps24. The rim101 ${Delta}$ strain (FI1) transformed with pFI1, a low-copy-number plasmid carrying HA-RIM101 and ADE3, formed red-only, nonsectoring colonies, whereas the same strain carrying pRS415 (vector) failed to grow on an LiCl-containing plate. The red-only, nonsectoring colony morphology indicated that LiCl tolerance was plasmid dependent. The parental strain for the screening, rim101 ${Delta}$ rim9 ${Delta}$ (FI10-5a) transformed with pFI1, failed to grow on LiCl-containing medium. Isolated LiCl-tolerant suppressor strains, rim101 ${Delta}$ rim9 ${Delta}$ did4-H1 (A6) and rim101 ${Delta}$ rim9 ${Delta}$ vps24-H1 (A108-9a), both transformed with pFI1, formed red-only, nonsectoring colonies on a plate containing LiCl because their LiCl tolerance was plasmid dependent. They formed white or sectoring colonies on a plate that did not contain LiCl because pFI1 was not then required. Cells were streaked on YPD and on YPD containing 0.21 M LiCl plates and incubated at 30°C for 11 days. (B) Defective Rim101 processing caused by rim9 ${Delta}$ is suppressed by did4 and vps24. The strains used in panel A were transformed with pRS415 (vector1) or pFI1, in combination with the empty YCp50 vector (vector2), pAS4163, a low-copy-number plasmid carrying DID4, or pAS311, a low-copy-number plasmid carrying VPS24, as indicated. Transformants were precultured in SD to logarithmic phase and then transferred to YPD. After a 3-h incubation, cells were collected, and cell lysates were prepared. Processed and unprocessed forms of HA-Rim101 (indicated) were detected by Western blotting with an anti-HA antibody.

In the same manner, 10 mutants were obtained that harbored rim21 ${Delta}$ suppressors among a total of 1.5 x 10⁷ clones. One mutationwas found to be dominant, and the other nine were found to berecessive (data not shown). Analysis of the dominant mutationwill be reported elsewhere. The recessive mutations obtainedwere classified into three complementation groups: C, D, andE, consisting of five, three, and one representative, respectively.As the mutants harboring the rim9 ${Delta}$ suppressors, these mutantsalso exhibited slow growth on SD plates and formed coloniesthat stained darker red on SD plates containing erythrosin B.Transformation of representative mutants of these groups withplasmids harboring either of DID4 or VPS24 revealed that thephenotypes of group C and E mutants were rescued by VPS24 andDID4, respectively (data not shown). Cloning of the gene thatrescued group D mutants identified VPS4 (8). To summarize, theseresults identified VPS24, VPS4, and DID4 as the genes correspondingto group C, D, and E mutants, respectively. Phenotypes of doublemutants constructed using rim21 ${Delta}$ and vps24 ${Delta}$ , vps4 ${Delta}$ , or did4 ${Delta}$ confirmedour conclusions (see below).

did4 ${Delta}$ , vps24 ${Delta}$ , and vps4 ${Delta}$ mutations constitutively activate the Rim101 pathway. To analyze the functions of Did4, Vps24, and Vps4 in the Rim101pathway, DID4, VPS24, and VPS4 disruptants were constructedin the S288C isogenic background, and processing of HA-Rim101was monitored by Western blotting. When wild-type cells weretransferred to an acidic condition (pH 3.5), HA-Rim101 was mostlyunprocessed (Fig. 2A, lane 2). On the other hand, when cellswere transferred to an alkaline condition (pH 7.5), most HA-Rim101was processed (Fig. 2A, lane 4). The degree of HA-Rim101 processingis between those of two conditions at pH 5.5 (Fig. 2A, lane3). The accumulation of processed Rim101 under alkaline conditionsand unprocessed form under acidic conditions are in good agreementwith previous observations (44).

In did4 ${Delta}$ mutants transferred to any condition of pH 3.5, 5.5,or 7.5, most HA-Rim101 was processed (Fig. 2A, lanes 5 to 7)as in wild-type cells at pH 7.5 (Fig. 2A, lane 4). This wasalso the case in vps24 ${Delta}$ mutants (Fig. 2A, lanes 8 to 10). Theseresults indicate that in did4 ${Delta}$ and vps24 ${Delta}$ mutants, HA-Rim101 processingoccurs constitutively in a medium pH-independent manner andthat both did4 ${Delta}$ and vps24 ${Delta}$ mutations constitutively activate theRim101 pathway. Also in vps4 ${Delta}$ mutants, HA-Rim101 processing wasconstitutive irrespective of medium pH (Fig. 2A, lanes 11 to13), although the degree of processing was less pronounced thanin did4 ${Delta}$ and vps24 ${Delta}$ mutants. These results indicate that in vps4 ${Delta}$ mutants, HA-Rim101 processing occurs constitutively at a lowlevel in a medium pH-independent manner and that a vps4 ${Delta}$ mutationmoderately activates the Rim101 pathway.

Constitutive activation of the Rim101 pathway in did4 ${Delta}$ , vps24 ${Delta}$ ,and vps4 ${Delta}$ mutants was confirmed by using a Rim101-responsivetranscriptional reporter. Lamb and Mitchell identified severaltarget genes for direct repression by Rim101, among which, YPL277Cwas most significantly upregulated by deficiency of the Rim101pathway (40). Therefore, a reporter plasmid was constructedby connecting the promoter segment of YPL277C to immediatelyupstream of the initiation codon of URA3. When the reporterplasmid was introduced into wild-type cells, cells did growon media lacking uracil at pH 4, where processing of Rim101was kept impeded, but not at pH 7, where processing of Rim101was stimulated (Fig. 2B). Cell grew poorly at pH 5.5 (Fig. 2B).Furthermore, when introduced into rim9 ${Delta}$ cells, in which processingof Rim101 did not occur irrespective of pH conditions, cellsdid grow on media lacking uracil at any of the three pH levels(Fig. 2B). These observations indicate that the reporter iseffective in monitoring activity of Rim101. When the reporterplasmid was introduced into did4 ${Delta}$ , vps24 ${Delta}$ , and vps4 ${Delta}$ mutants, cellsdid not grow on media lacking uracil at any of the pH conditionsexamined (Fig. 2B). This result again shows that Rim101 is keptactive irrespective of pH conditions in these three mutants.

Epistasis relationship between rim mutations and did4, vps24, or vps4. We then examined whether did4 ${Delta}$ , vps24 ${Delta}$ , or vps4 ${Delta}$ were able to suppressrim8 ${Delta}$ , rim9 ${Delta}$ , rim20 ${Delta}$ , rim21 ${Delta}$ , or rim13 ${Delta}$ . rim8 ${Delta}$ , rim9 ${Delta}$ , rim20 ${Delta}$ , rim21 ${Delta}$ ,and rim13 ${Delta}$ mutants were defective in HA-Rim101 processing (Fig.3A, lanes 3, 5, 7, 9, and 11) and sensitive to LiCl (Fig. 3B)as described previously. The double mutants rim8 ${Delta}$ did4 ${Delta}$ , rim9 ${Delta}$ did4 ${Delta}$ , and rim21 ${Delta}$ did4 ${Delta}$ were capable of HA-Rim101 processing (Fig.3A, upper panel, lanes 4, 6, and 10) and tolerant of LiCl (Fig.3B). These observations indicate that rim8 ${Delta}$ , rim9 ${Delta}$ , and rim21 ${Delta}$ were suppressed by did4 ${Delta}$ . In contrast, the double mutants rim20 ${Delta}$ did4 ${Delta}$ and rim13 ${Delta}$ did4 ${Delta}$ were defective in HA-Rim101 processing (Fig.3A, upper panel, lanes 8 and 12) and sensitive to LiCl (Fig.3B, upper panel), indicating that rim20 ${Delta}$ and rim13 ${Delta}$ were not suppressedby did4 ${Delta}$ . This was also the case for the double mutants withvps24 ${Delta}$ (Fig. 3A, middle panel, lanes 4, 6, 8, 10, and 12, andFig. 3B, middle panel) and vps4 ${Delta}$ (Fig. 3A, lower panel, lanes4, 6, 8, 10 and 12, and Fig. 3B, lower panel). These observationsindicate that rim8 ${Delta}$ , rim9 ${Delta}$ , and rim21 ${Delta}$ were suppressed but thatrim20 ${Delta}$ and rim13 ${Delta}$ were not suppressed by vps24 ${Delta}$ or vps4 ${Delta}$ , althoughvps4 mutations were not isolated in our screen for suppressorsof rim9 ${Delta}$ . The observations that rim20 and rim13 were epistaticto did4, vps24, and vps4, whereas did4, vps24, and vps4 wereepistatic to rim8, rim9, and rim21 provide the genetic evidencethat Rim8, Rim9, and Rim21 function upstream of Rim20 and Rim13in the Rim101 pathway.

Relative to the double mutants rim8 ${Delta}$ did4 ${Delta}$ , rim9 ${Delta}$ did4 ${Delta}$ , rim21 ${Delta}$ did4 ${Delta}$ ,rim8 ${Delta}$ vps24 ${Delta}$ , rim9 ${Delta}$ vps24 ${Delta}$ , and rim21 ${Delta}$ vps24 ${Delta}$ , HA-Rim101 processingwas more pronounced in did4 ${Delta}$ and vps24 ${Delta}$ mutants (Fig. 3A, upperand middle panels, lanes 2, 4, 6, and 10). These results indicatethat even in did4 ${Delta}$ and vps24 ${Delta}$ mutants, Rim8, Rim9, and Rim21 stillfunction to facilitate Rim101 processing (see Discussion).

Epistasis relationship between the Rim101 pathway-inactivating ESCRT mutations and did4 or vps24. Recently, it is reported that ESCRT-I components Stp22, Vps28,and Srn2, ESCRT-II components Snf8, Vps25, and Vps36, and ESCRT-IIIcomponents Snf7 and Vps20 are required for Rim101 processing,just as are Rim8, Rim9, Rim13, Rim20, and Rim21 (80). Our ownindependent analysis had reached conclusions largely consistentwith these results, with the sole exception of Srn2, which wasdispensable for HA-Rim101 processing and LiCl tolerance in ouranalysis (see Discussion). We then examined whether did4 ${Delta}$ orvps24 ${Delta}$ was able to suppress phenotypes of mutants defective inthese ESCRT components with respect to HA-Rim101 processingand LiCl tolerance.

stp22 ${Delta}$ , vps28 ${Delta}$ , snf8 ${Delta}$ , vps25 ${Delta}$ , vps36 ${Delta}$ , snf7 ${Delta}$ , and vps20 ${Delta}$ mutants werecommonly defective in HA-Rim101 processing (Fig. 4A, lanes 3,5, 7, 9, and 11, and Fig. 4C, lanes 4 and 7) and sensitive toLiCl (Fig. 4B and 4D) as described above. In contrast, stp22 ${Delta}$ vps24 ${Delta}$ and vps28 ${Delta}$ vps24 ${Delta}$ double mutants were capable of HA-Rim101processing (Fig. 4A, lanes 4 and 6) and tolerant of LiCl (Fig.4B). Similarly, an snf8 ${Delta}$ vps24 ${Delta}$ double mutant was moderately proficientin HA-Rim101 processing (Fig. 4A, lane 8) and somewhat tolerantof LiCl (Fig. 4B). vps25 ${Delta}$ vps24 ${Delta}$ , vps36 ${Delta}$ vps24 ${Delta}$ , snf7 ${Delta}$ vps24 ${Delta}$ , andvps20 ${Delta}$ vps24 ${Delta}$ double mutants were, however, defective in HA-Rim101processing (Fig. 4A, lanes 10 and 12, and Fig. 4D, lanes 6 and9) and sensitive to LiCl (Fig. 4B and 4D). snf7 ${Delta}$ did4 ${Delta}$ and vps20 ${Delta}$ did4 ${Delta}$ double mutants were also defective in HA-Rim101 processing(Fig. 4C, lanes 5 and 8) and sensitive to LiCl (Fig. 4D).

These results can be summarized as follows. Both defective Rim101processing and LiCl sensitivity caused by ESCRT-I mutationsstp22 ${Delta}$ and vps28 ${Delta}$ were suppressed by vps24 ${Delta}$ , those caused by ESCRT-IImutation snf8 ${Delta}$ were moderately suppressed, and those caused byESCRT-II mutations vps25 ${Delta}$ and vps36 ${Delta}$ and ESCRT-III mutations snf7 ${Delta}$ and vps20 ${Delta}$ were not suppressed by vps24 ${Delta}$ .

DISCUSSION

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Discussion

New mutants that exhibit constitutive activation of the Rim101 pathway. As of this writing, the only pathway-activating mutants thathave been reported in the Rim101 pathway harbor dominant allelesof RIM101 encoding proteins with C-terminal truncations thatmimic proteolytic processing (44). In the current study, weidentified did4, vps24, and vps4 as pathway-activating mutantsof the Rim101 pathway that are alkaline-mimicking. In our experimentalsystem, most of the HA-Rim101 pool in wild-type cells remainedunprocessed under acidic conditions (pH 3.5). The extent ofprocessing increased as medium pH rose, and under alkaline conditions(pH 7.5) most of the HA-Rim101 pool was processed. In did4 orvps24 mutants, constitutive proteolytic processing of Rim101was observed that occurs irrespective of medium pH. The extentof the processing was comparable to that induced in wild-typecells under alkaline conditions. In addition, did4 and vps24mutations were found to suppress defective Rim101 processingin rim8, rim9, and rim21 mutants. Similarly, in vps4 mutants,Rim101 processing was observed even under conditions of acidicpH, although the extent of processing was less than in did4or vps24 mutants. Consistent with this, rim8, rim9, and rim21were also modestly suppressed by vps4.

Order of action among the Rim proteins and the ESCRT components. Identification of did4, vps24, and vps4 as Rim101 pathway-activatingmutants enabled us to perform a new set of epistasis tests thatshowed that Rim8, Rim9, and Rim21 function upstream of bothRim20 and Rim13 in the pathway. This conclusion is consistentwith the report that Rim20 directly interacts with Rim101 (79)and also with a long-standing conjecture that calpain-like Rim13is the protease directly catalyzing Rim101 processing. The threecomponents placed upstream of Rim13 and Rim20, namely, putativemembrane proteins Rim9 and Rim21, as well as Rim8, may constitutethe pH-sensing machinery of the pathway (see below).

In contrast to the two pathway-activating mutants, did4 andvps24, most other mutants defective in ESCRT components, i.e.,stp22, vps28, snf8, vps25, vps36, snf7, and vps20, show impairedRim101 processing, as well as LiCl sensitivity, with the onlyexception being srn2 (see below). In this respect, these mutantsshare the phenotypes with rim8, rim9, rim20, rim21, and rim13mutants. Therefore, epistasis tests similar to those conductedfor the rim mutations were performed for these ESCRT mutations.Both defective Rim101 processing and LiCl sensitivity of stp22and vps28 were suppressed by vps24, those of snf8 were moderatelysuppressed, and those of vps25, vps36, snf7, and vps20 werenot suppressed at all by vps24. These observations suggest thatcomponents of ESCRT-II, especially Vps25 and Vps36, and componentsof ESCRT-III, Snf7 and Vps20, play more important roles thanthose of ESCRT-I with respect to Rim101 processing. This isin line with previous genetic evidence indicating that ESCRT-IIacts downstream of, and plays a more fundamental role than,ESCRT-I in MVB sorting (6).

Xu et al. reported that Rim101 processing is also deficientin an srn2 ${Delta}$ mutant (80). In contrast, an srn2 ${Delta}$ mutant was capableof Rim101 processing and tolerant of LiCl in our analysis, whichwas the only exception among mutants defective in ESCRT components(data not shown). Bowers et al. also reported that srn2 mutantsare tolerant of LiCl (13), but Eguez et al. reported that thesemutants were sensitive (22). The reason for the discrepancyis currently unclear but may reflect somewhat milder phenotypesof srn2 mutants relative to other mutants in ESCRT components,as observed in a higher restrictive temperature for growth,for example (data not shown).

Possible explanation for previously reported phenotypic differences among mutants defective in different ESCRT components. The disparity in Rim101 processing explains the difference inLiCl sensitivity among mutants defective in different ESCRTcomponents. Full expression of ENA1, whose product is responsiblefor Li⁺ efflux, requires processing of Rim101, and the facthence is consistent with the observation that did4 and vps24mutants are tolerant of LiCl and mutants defective in otherESCRT components sensitive (28, 40, 41). The disparity in Rim101processing may also explain several previously unaddressed qualitativephenotypic differences among different ESCRT mutants. CPS, aselective cargo of MVB sorting, is reported to display differentprocessing patterns in different ESCRT mutants (5). In snf7 ${Delta}$ and vps20 ${Delta}$ mutants, CPS was processed by the hydrolytic enzymesaccumulated in the "class E" compartment, although in a slightlydifferent pattern than occurs in wild-type cells. In contrast,CPS processing was impeded in did4 ${Delta}$ , vps24 ${Delta}$ , and vps4 ${Delta}$ mutants.The deficiency in CPS processing in did4 ${Delta}$ , vps24 ${Delta}$ , and vps4 ${Delta}$ mutantshas been interpreted as a result of CPS being protected fromproteolysis by sequestration or concentration in a compartmentwith a specific role for the Snf7-Vps20 subcomplex (5). Herewe propose a different explanation. Lamb and Mitchell identifiedPRB1, which encodes a major vacuolar protease that catalyzesCPS processing, as a target gene for repression by Rim101 (40).Therefore, in did4 ${Delta}$ , vps24 ${Delta}$ , and vps4 ${Delta}$ mutants, proteolytic activityof Prb1p is likely low due to transcriptional repression byRim101, and thus the low Prb1 activity will in turn result indeficient CPS processing. The previously reported differencesin the sensitivity to Ca²⁺, Mn²⁺, and calcofluor white amongmutants in different ESCRT components may also be attributedto the disparity in Rim101 processing (22, 66).

Mechanism for constitutive proteolytic processing of Rim101 in did4, vps24, and vps4 mutants. Although all of the "class E" vps mutants share the same defectiveMVB sorting phenotype, only did4, vps24, and vps4 mutants exhibitthe constitutive proteolytic processing of Rim101. In contrast,the other mutants in ESCRT components, except for srn2, exhibitdefective Rim101 processing. Furthermore, all non-ESCRT "classE" vps mutants except for vps4 are normal in Rim101 processing.This difference in Rim101 processing among the "class E" vpsmutants indicates that defective MVB sorting itself does notcause constitutive Rim101 processing. Then, what is the mechanismthat underlies constitutive Rim101 processing?

According to the seminal studies on the ESCRT complexes by Emrand coworkers, did4, vps24, and vps4 mutants commonly accumulatethe Vps20-Snf7 subcomplex of ESCRT-III on the endosomal membrane(5, 8, 9). This accumulation is not observed in other mutantsin ESCRT components (5). In contrast, Emr and coworkers haveshown that many other mutants in ESCRT components are defectivein formation and endosomal membrane loading of ESCRT-III. Ourresults reveal a consistent correlation between the reportedmembrane loading of Vps20-Snf7 and Rim101 processing. First,not only defects in Vps20 or Snf7 itself but also defects inESCRT-I or ESCRT-II have been shown to prevent loading of Vps20-Snf7onto the endosomal membrane (6). Concomitantly, mutants in ESCRT-Ior ESCRT-II components are defective in Rim101 processing, withthe sole exception of srn2 (see above). Second, in a vps4 background,ESCRT-II is required but ESCRT-I is not required for loadingof Vps20-Snf7 on the endosomal membrane (6). This again is ingood agreement with the results of our epistasis tests thatshow that defective Rim101 processing of the ESCRT-I mutantsstp22 and vps28 is suppressed by vps24 but that of ESCRT-IImutants vps25 and vps36 is not. An exceptional component ofESCRT-II in this respect is Snf8, in that defective Rim101 processingin a snf8 mutant is partially suppressed by vps24. Because possibleaccumulation of Vps20-Snf7 on the endosomal membrane in snf8did4, snf8 vps24, or snf8 vps4 double mutants has not been examined,this point requires further study.

In light of these observations, we propose that either formationor the endosomal membrane loading of the Vps20-Snf7 subcomplexactivates proteolytic processing of Rim101. On the other hand,it has already been suggested that a complex of Rim20-Snf7-Rim13is responsible for catalyzing proteolytic processing of Rim101(79). Extending this model, we then propose the following mechanismfor constitutive proteolytic processing of Rim101 in did4, vps24,and vps4 mutants (Fig. 5). In these mutants, the Vps20-Snf7subcomplex of ESCRT-III accumulates on the endosomal membrane.To this subcomplex, Rim20 and Rim13 are recruited to form ahigher-order complex consisting of Rim20-(Vps20-Snf7)-Rim13through an interaction between Rim20 and Snf7 and between Snf7and Rim13. The formation of this complex, we propose, promotesproteolytic processing of Rim101 by recruiting Rim101 throughinteraction with Rim20 and thereby presenting it to activatedRim13. To test this model, localization of components of theRim101 pathway and the ESCRT complexes need to be determinedat different pH values or in various mutants of ESCRT components.

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FIG. 5. Model for activation of Rim101 proteolytic processing by components of the Rim101 pathway; ESCRT-I, -II, and -III components; and Vps4 upon exposure to alkaline pH. See Discussion for a detailed explanation of this model.

vps4 mutants exhibit constitutive processing of Rim101, althoughthe extent of processing seems moderate relative to what wasobserved in did4 and vps24 mutants. This may be explained asfollows. In vps4 mutants, the Did4-Vps24 subcomplex is loadedonto the Vps20-Snf7 subcomplex on the endosomal membrane (5,9) and potentially competes with Rim20 and/or Rim13 for bindingto Vps20-Snf7. In contrast, in did4 and vps24 mutants Did4-Vps24does not exist, and thus Vps20-Snf7 is fully available for bindingto Rim20 and/or Rim13.

Mechanism for alkaline-responsive proteolytic processing of Rim101. By extending the above discussion on constitutive processingof Rim101 in did4 ${Delta}$ , vps24 ${Delta}$ , and vps4 ${Delta}$ mutants to the alkaline pH-responsiveprocessing of Rim101 in wild-type cells, we propose that a similarmechanism operates in both processes. In this model, a complexof Rim20-(Vps20-Snf7)-Rim13 forms under conditions of alkalinepH in a Rim8-, Rim9-, and Rim21-dependent manner (Fig. 5). Theconcrete mechanism by which Rim8, Rim9, and Rim21 promote formationof the Rim20-(Vps20-Snf7)-Rim13 complex remains to be determined,although it is clear that formation of the complex also requiresboth ESCRT-I and ESCRT-II. Even in did4 or vps24 mutants, Rim8,Rim9, and Rim21 still play some role in facilitating Rim101processing, because defective Rim101 processing in rim8, rim9,and rim21 mutants is not fully restored, even when suppressedby did4 or vps24: in did4 cells for example, the extent of Rim101processing is more pronounced than in rim8 did4 cells. One speculativepossibility is that, by mimicking cargo proteins for MVB sorting,either Rim9 or Rim21 recruits ESCRT-I onto the endosomal membrane,thereby promoting formation of the Rim20-(Vps20-Snf7)-Rim13complex under alkaline conditions. If the recruitment of ESCRT-Idepends on ubiquitination of Rim9 or Rim21, as is the case forknown cargo proteins, the ubiquitination should occur in analkaline pH-dependent manner. This point remains to be determined.Stimulation-dependent ubiquitination and endosomal sorting arecommon modes of desensitization of membrane receptors/sensors(34), and this model proposes a variant of this common mechanismthat makes use of recruitment of ESCRT complexes not for downregulation,but for signaling itself.

Physiological significance of the link between the Rim101 pathway and MVB sorting. We have shown a close relationship between the Rim101 pathwayand MVB sorting. What is the physiological significance of thislink? MVB sorting requires a pH gradient across the endosomalmembrane. In fact, efficient sorting of vacuolar proteins isimpaired under alkaline conditions (36). In addition, mutationalor pharmacological inactivation of the vacuolar H⁺-ATPase, whichdisrupt acidification of the vacuolar, and perhaps the endosomal,compartment also causes defective vacuolar protein sorting (10,36, 52, 64, 75, 81). The defects in MVB sorting under theseconditions may arise from impaired formation of MVB. Consistentwith this, Matsuo et al. reported that formation of MVB-likeliposomes in an in vitro system required a pH gradient acrossthe liposome membrane that reproduced the in vivo lumenal acidicpH of the endosome (49). If impairment in MVB formation underalkaline conditions blocks the process of MVB sorting afterthe step of ESCRT-III loading, as in did4, vps24, or vps4 mutants,formation of the active Rim20-(Vps20-Snf7)-Rim13 complex wouldbe promoted under these conditions. This implies that failureto maintain a pH gradient across the endosomal membrane underalkaline conditions can be coupled with activation of the Rim101pathway. This will ensure, in theory at least, the appropriateresponse of the Rim101 pathway to raises in environmental pH.

Finally, it should be noted that all of the components of theaforementioned protease complex have one or more mammalian homologs.Rim13 is the only calpain homolog in yeast, whereas humans have14 genes for calpains, including PalBH/calpain 7, which is mostsimilar to Rim13 (23, 24, 26, 70). The human homologs of Rim20,Snf7, and Vps20 are Alix/AIP1, CHMP4/hSnf7, and hVps20, respectively(32, 51, 58, 76). The existence of these homologs suggests thata similar mechanism might operate in mammalian cells. The possibilityof calpain functioning at the membranes is also implied by thepresent study. Indeed, recent studies have shown that conventionalcalpains localize and function at the endoplasmic reticulumand the lysosome (11, 57, 71). Elucidation of the mechanismthat regulates activation of the Rim101 pathway should shedfurther light on the biology of calpains in general.

ACKNOWLEDGMENTS

We thank Fred Winston, Janice Kranz, Konnie Holm, Mark Longtine,Yoichi Noda, and Koji Yoda for yeast strains and plasmids. Wealso thank Eugene Futai, Koichi Suzuki, and all of the membersof the Maeda laboratory for help, advice, and discussion.

This study was supported in part by a Grant-in-Aid for ScientificResearch on Priority Areas (KAKENHI 14086203) from the Ministryof Education, Culture, Sports, Science, and Technology (MEXT)and a grant (no. 0349) from the Salt Science Research Foundation(both to T.M.).

FOOTNOTES

* Corresponding author. Mailing address: Institute of Molecular and Cellular Biosciences, The University of Tokyo, 1-1-1 Yayoi, Bunkyo-ku, Tokyo 113-0032, Japan. Phone: 81-3-5841-7820. Fax: 81-3-5841-7899. E-mail: maeda{at}iam.u-tokyo.ac.jp.

REFERENCES

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