Nonredundant Roles of Mitochondria-associated F-Box Proteins Mfb1 and Mdm30 in Maintenance of Mitochondrial Morphology in Yeast

Mark Dürr^*, Mafalda Escobar-Henriques, Sandra Merz^*, Stefan Geimer^*^,, Thomas Langer, and Benedikt Westermann^*^,^,

*Institut für Zellbiologie, Abteilung für Elektronenmikroskopie, and Bayreuther Zentrum für Molekulare Biowissenschaften, Universität Bayreuth, 95440 Bayreuth, Germany; and Institut für Genetik, Universität zu Köln, 50674 Köln, Germany

Submitted January 18, 2006; Revised June 7, 2006; Accepted June 8, 2006
Monitoring Editor: Sandra Schmid

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Mitochondria constantly fuse and divide to adapt organellarmorphology to the cell’s ever-changing physiological conditions.Little is known about the molecular mechanisms regulating mitochondrialdynamics. F-box proteins are subunits of both Skp1-Cullin-F-box(SCF) ubiquitin ligases and non-SCF complexes that regulatea large number of cellular processes. Here, we analyzed theroles of two yeast F-box proteins, Mfb1 and Mdm30, in mitochondrialdynamics. Mfb1 is a novel mitochondria-associated F-box protein.Mitochondria in mutants lacking Mfb1 are fusion competent, butthey form aberrant aggregates of interconnected tubules. Incontrast, mitochondria in mutants lacking Mdm30 are highly fragmenteddue to a defect in mitochondrial fusion. Fragmented mitochondriaare docked but nonfused in ${Delta}$ mdm30 cells. Mitochondrial fusionis also blocked during sporulation of homozygous diploid mutantslacking Mdm30, leading to a mitochondrial inheritance defectin ascospores. Mfb1 and Mdm30 exert nonredundant functions andlikely have different target proteins. Because defects in F-boxprotein mutants could not be mimicked by depletion of SCF complexand proteasome core subunits, additional yet unknown factorsare likely involved in regulating mitochondrial dynamics. Wepropose that mitochondria-associated F-box proteins Mfb1 andMdm30 are key components of a complex machinery that regulatesmitochondrial dynamics throughout yeast’s entire lifecycle.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Mitochondria carry out a variety of different functions in eukaryoticcells. They supply the cell with ATP generated by oxidativephosphorylation, they are the site of many anabolic and catabolicpathways, they play an essential role in the assembly of Fe/Sclusters, and they are key regulators of programmed cell death(Scheffler, 2000; Lill and Mühlenhoff, 2005; Youle andKarbowski, 2005). Depending on the cell’s physiologicalconditions, mitochondria frequently change their shape and intracellularposition (Bereiter-Hahn, 1990; Yaffe, 1999; Griparic and vander Bliek, 2001; Westermann, 2002; Mozdy and Shaw, 2003; Scottet al., 2003; Chen and Chan, 2004). This dynamic behavior isimportant for a number of cellular processes. For example, mitochondrialfusion is required for sperm development in Drosophila (Halesand Fuller, 1997), for embryonic development in mice (Chen etal., 2003), and for maintenance of mitochondrial DNA in yeast(Chen and Butow, 2005). Conversely, mitochondrial division playsa crucial and evolutionarily highly conserved role in the apoptoticpathway (Jagasia et al., 2005; Youle and Karbowski, 2005). Althoughseveral proteins mediating mitochondrial motility, fusion andfission have been identified during the past several years (Okamotoand Shaw, 2005), little is known about regulatory componentsof mitochondrial dynamics.

The core machinery mediating mitochondrial membrane fusion inyeast consists of three proteins, namely, Fzo1, a conservedGTPase in the outer membrane (Hermann et al., 1998; Rapaportet al., 1998); the outer membrane protein Ugo1 (Sesaki and Jensen,2001); and Mgm1, a conserved GTPase located in the intermembranespace (Wong et al., 2000). Ugo1 physically interacts with Fzo1and Mgm1 and presumably coordinates their function (Wong etal., 2003; Sesaki and Jensen, 2004). Genetic and morphologicalevidence suggests that the mitochondrial fusion and fissionmachineries act antagonistically and operate in a perfectlybalanced manner. Defects in cells lacking components of thefusion machinery can be relieved by deletion of genes encodingproteins of the fission machinery (Bleazard et al., 1999; Sesakiand Jensen, 1999). Wild-type cells growing logarithmically onglucose-containing medium show tightly balanced mitochondrialfusion and fission activities at a rate of 1.7 fusion and fissionevents per minute and cell (Jakobs et al., 2003). Thus, fusionand fission must be strictly coordinated to maintain a reticularmitochondrial network. A regulatory role in mitochondrial fusionhas been proposed for Pcp1, a rhomboid-like protease in themitochondrial inner membrane. Pcp1 generates two isoforms ofMgm1 by site-specific processing (Herlan et al., 2003; McQuibbanet al., 2003; Sesaki et al., 2003). It has been suggested thatPcp1-dependent processing of Mgm1 adapts mitochondrial fusionactivity to the ATP requirements of the cell (Herlan et al.,2004).

F-box proteins are particularly versatile regulators of a varietyof cellular functions (Willems et al., 2004; Petroski and Deshaies,2005). Typically, they serve as substrate adaptors in Skp1-Cullin-F-box(SCF) E3 ubiquitin ligases, where they are required to targetproteins to ubiquitylation and degradation by the 26S proteasome.However, some F-box proteins may also function independentlyof the SCF complex and the 26S proteasome (Galan et al., 2001).In budding yeast, at least 21 proteins contain a discernibleF-box motif (Willems et al., 2004). One of these proteins, Mdm30,is required for maintenance of fusion-competent mitochondria(Fritz et al., 2003). A subfraction of Mdm30 is associated withmitochondria (Fritz et al., 2003; Sickmann et al., 2003), andcells lacking Mdm30 contain aggregated or fragmented mitochondria,tend to lose their mitochondrial DNA, and fail to fuse mitochondriain vivo. The steady-state level of Fzo1 is dependent on thecellular level of Mdm30, suggesting that Mdm30 regulates mitochondrialfusion by directly or indirectly stimulating degradation ofFzo1 (Fritz et al., 2003). However, recent results by Neutznerand Youle (2005) suggest that the situation may be more complex.These authors showed that treatment of yeast cells with themating pheromone ${alpha}$ factor evokes a fragmentation of the mitochondrialnetwork into small pieces. Mitochondrial fragmentation is accompaniedby proteasome-dependent degradation of Fzo1 but does not requireMdm30 (Neutzner and Youle, 2005; Escobar-Henriques et al., 2006).These results point to the existence of multiple pathways forthe regulation of the mitochondrial fusion machinery. To gainmore insights into the role of F-box proteins in the regulationof mitochondrial behavior, we analyzed the functions of Mdm30and Mfb1, a novel mitochondria-associated F-box protein, invegetatively growing cells and during mating and sporulation.

MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Plasmid Constructions
Standard methods were used for cloning procedures. The plasmidfor expression of Mfb1 from the GAL1 promoter in yeast, pYES-MFB1,was generated by PCR amplification of the mitochondria-associatedF-box protein 1 (MFB1) coding region from genomic yeast DNAusing primers 5'-AAA AAG CTT ATG ACA TTA TTT TCT TGT AGT GTAC-3' and 5'-AAA GGA TCC TTA TAT ATT AAA ATC GGT ATT AGC G-3'and cloning into the HindIII/BamHI sites of vector pYES2.0 (Invitrogen,Groningen, The Netherlands). Plasmid pYES-MDM30 for expressionof Mdm30 from the GAL1 promoter has been described previously(Fritz et al., 2003). Plasmids pVT100U-mtGFP, pYX113-mtGFP (Westermannand Neupert, 2000), pRS416-GAL1+PrF₀ATP9-RFP (Mozdy et al.,2000), and pSJ55 (Jakobs et al., 2003) were used for expressionof mitochondria-targeted green fluorescent protein (GFP) ormitochondria-targeted DsRed. Plasmids for expression of FLAG-taggedMdm30 and an F-box–less variant thereof under controlof the CUP1 promoter are described by Escobar-Henriques et al.(2006). A plasmid for expression of FLAG-tagged Mfb1 under controlof the CUP1 promoter (pJDCEX2-MFB1) was constructed by PCR amplificationof the MFB1 coding region using primers 5'-AAA AAG ATC TAT GACATT ATT TTC TTG TAG TGT AC-3' and 5'-AAA ACC CGG GTT ATA TATTAA AAT CGG TAT TAG GC-3' and cloning into the BglII/XmaI sitesof pJDCEX2-MDM30 (Escobar-Henriques et al., 2006). A plasmidfor expression of a truncated Mfb1 protein lacking the 60 N-terminalamino acids (pJDCEX2-MFB1- ${Delta}$ F-box) was constructed the same wayusing forward primer 5'-AAA AAG ATC TGT TAT CGG CTC AAA CGGGAA TAT G-3'.

Construction and Manipulation of Yeast Strains
Growth and manipulation of yeast strains was according to publishedprocedures (Sherman, 1991; Sherman and Hicks, 1991; Gietz etal., 1992). All strains used in this study are isogenic to BY4741,BY4742, and BY4743 (Brachmann et al., 1998). Haploid deletionstrains (Giaever et al., 2002) were obtained from EUROSCARF(Frankfurt, Germany), and strains expressing essential genesunder control of a titratable promoter (Mnaimneh et al., 2004)were obtained from BioCat (Heidelberg, Germany). A strain expressingMfb1-GFP (Huh et al., 2003) was obtained from Invitrogen. Mitochondriahave a wild-type–like appearance in this strain, indicatingthat the Mfb1-GFP fusion protein is functional (Figure 1B; ourunpublished observations). Homozygous diploid wild-type and ${Delta}$ mfb1 and ${Delta}$ mdm30 mutants expressing mitochondria-targeted GFPhave been described previously (Dimmer et al., 2002). A haploiddouble mutant, ${Delta}$ mfb1/ ${Delta}$ mdm30, was generated by mating of haploiddeletion strains, sporulation, and tetrad dissection. Genotypesof haploid progeny were determined by PCR. Promoter shutoffin cdc4, cdc34, cdc53, ctf13, met30, and pre1 mutants carryingtitratable promoter alleles (Mnaimneh et al., 2004) was as describedpreviously (Altmann and Westermann, 2005). Expression of FLAG-taggedMfb1 and Mdm30 proteins and ${Delta}$ F-box variants thereof was inducedby addition of 100 µM CuSO₄ to the medium. Assay of mitochondrialfusion in vivo was according to published procedures (Nunnariet al., 1997; Fritz et al., 2003). Mitochondrial behavior duringsporulation was observed essentially as described previously(Gorsich and Shaw, 2004) with minor modifications. Before sporulation,strains were incubated for 3 d on yeast extract-peptone-dextrose(YPD) plates at 30°C. Cells were allowed to form tetradsfor 12 d at 30°C in liquid sporulation medium (1% potassiumacetate; 20 µg/ml each of adenine, arginine, histidine,methionine, and tryptophan; and 30 µg/ml each of isoleucine,leucine, lysine, phenylalanine, threonine, and valine).

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Figure 1. Mfb1 is a novel mitochondria-associated F-box protein. (A) The F-box motifs of Mfb1 (amino acid residues 17–60) and Mdm30 (amino acid residues 16–59) are aligned with an F-box consensus sequence according to Willems et al. (2004)

. Favored sites in the consensus sequence are in uppercase letters, and moderately well tolerated residues are in lowercase letters. Residues matching the consensus sequence are in red. (B) Yeast cells expressing an Mfb1-GFP fusion protein under control of the MFB1 promoter were grown to log phase in glucose-containing medium (YPD), and mitochondria were stained with the membrane potential-sensitive dye rhodamine B hexyl ester. Yeast cells were analyzed by fluorescence and differential interference contrast (DIC) microscopy. Rhodamine fluorescence (mito) was analyzed first to avoid photoconversion of GFP. Bar, 1 µm.

Microscopy
Yeast cultures were grown at 30°C in liquid YPD medium tomid-logarithmic growth phase, if not indicated otherwise. Mitochondriawere stained with plasmid-expressed mitochondria-targeted GFPor DsRed (see above) or rhodamine B hexyl ester (Invitrogen,Eugene, OR) as described previously (Dimmer et al., 2002

). Filamentousactin, vacuoles, and endoplasmic reticulum (ER) were stainedas described previously (Fritz et al., 2003

). Epifluorescencemicroscopy was performed using an Axioplan 2 microscope (CarlZeiss Lichtmikroskopie, Göttingen, Germany) equipped witha Plan-Neofluar 100x/1.30 Ph3 oil objective (Carl Zeiss Lichtmikroskopie).Images were recorded with an Evolution VF Mono Cooled monochromecamera (Intas, Göttingen, Germany) and processed with Image-ProPlus 5.0 and Scope Pro4.5 software (Media Cybernetics, SilverSpring, MD).

Assay of Fzo1 Turnover after ${alpha}$ Factor-induced Cell Cycle Arrest
To examine Fzo1 degradation upon ${alpha}$ factor-induced cell cyclearrest (Neutzner and Youle, 2005), early log phase cells grownon YPD medium were treated with 20 mM sodium citrate and 10µM ${alpha}$ factor. At the indicated time points, cells correspondingto 3 optical density units were collected, lysed at alkalinepH, and trichloroacetic acid (TCA)-precipitated (Tatsuta andLanger, 2006), and protein extracts were analyzed by SDS-PAGEand immunoblotting using antisera against the GTPase domainof Fzo1 (kind gift from Jodi Nunnari, University of California,Davis, CA).

Assay of Mdm30 Binding to Mitochondria
Yeast cells expressing FLAG-tagged Mdm30 and Mdm30- ${Delta}$ F-box weregrown to logarithmic growth phase in SC medium lacking leucineto select for maintenance of the plasmid. The experiment wasperformed at intermediate Mdm30 expression levels, i.e., withoutthe addition of copper to the medium. Total cell extracts wereprepared as described above. Crude mitochondria were isolatedby differential centrifugation, and soluble proteins were precipitatedfrom the supernatant with TCA (Escobar-Henriques et al., 2006).Total cell proteins, mitochondrial proteins, and cytosolic proteinswere analyzed by SDS-PAGE and immunoblotting.

Electron Microscopy
Yeast cells were prepared for electron microscopy accordingto published protocols (Bauer et al., 2001) with the exceptionthat embedding was in Spurr’s resin (Spurr, 1969). Ultrathinsections (70 nm) were cut with a diamond knife (MicroStar, Huntsville,TX) on a Leica Ultracut UCT microtome (Leica Microsystems, Vienna,Austria) and mounted on pioloform-coated copper grids. Sectionswere viewed with a Zeiss CEM 902 A transmission electron microscope(Carl Zeiss, Oberkochen, Germany) at 80 kV. Micrographs weretaken using SO-163 EM film (Eastman Kodak, Rochester, NY). Three-dimensionalreconstructions were prepared from scanned films using IMODsoftware, version 3.5.5 (http://bio3d.colorado.edu/imod/; Kremeret al., 1996).

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Mfb1 Is a Novel Mitochondria-associated F-Box Protein
The MFB1 gene (mitochondria-associated F-box protein 1; systematicname YDR219c) encodes a protein of 465 amino acid residues ( ${approx}$ 53kDa). Similar to Mdm30, the Mfb1 protein contains an F-box motifat its N terminus (Figure 1A). Outside the F-box, the Mfb1 aminoacid sequence does not show significant homology to any otherknown protein domain or sequence motif. In a large-scale analysisaimed at the systematic identification of protein complexesby mass spectrometry, Mfb1 was found in a complex with Skp1(Ho et al., 2002). A large-scale analysis aimed at the systematicsubcellular localization of the yeast proteome suggested thatMfb1 is associated with mitochondria, because expression ofan Mfb1-GFP fusion protein yielded a staining pattern resemblingmitochondria (Huh et al., 2003). To prove a mitochondrial locationof Mfb1, we stained live yeast cells expressing Mfb1-GFP undercontrol of its endogenous promoter with a mitochondria-specificfluorescent dye, rhodamine B hexyl ester. Because Mfb1-GFP stainingoverlapped with mitochondrial staining (Figure 1B), we concludethat a major fraction of Mfb1 is associated with mitochondria.

Mfb1, Mdm30, and SCF Core Subunits Play Distinct and Separable Roles in Mitochondrial Distribution and Morphology
To investigate a role of Mfb1 in mitochondrial biogenesis andbehavior, and to address the question whether its function overlapswith Mdm30, we constructed and analyzed mutant strains lackingor overexpressing the two mitochondria-associated F-box proteinsin various combinations. Cells lacking Mfb1 showed a slightgrowth defect on the nonfermentable carbon source glycerol atelevated temperature (Figure 2A), which was less pronouncedthan the growth defect of cells lacking Mdm30 (Figure 2A; Fritzet al., 2003). The growth behavior of the ${Delta}$ mfb1/ ${Delta}$ mdm30 doublemutant was identical to that of the ${Delta}$ mdm30 single mutant (Figure 2A).We conclude that both Mfb1 and Mdm30 are important for maintenanceof respiratory functions at elevated temperature, but yeastcells can tolerate the simultaneous loss of both proteins withoutthe loss of vital functions.

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Figure 2. Mfb1, Mdm30, SCF complex, and proteasome subunits are required for normal growth and mitochondrial morphology. (A) Wild-type (WT), ${Delta}$ mfb1, ${Delta}$ mdm30, and ${Delta}$ mfb1/ ${Delta}$ mdm30 ( ${Delta}$ ${Delta}$ ) cells were grown overnight in glucose-containing medium at 30°C. Then, 10-fold serial dilutions were spotted onto plates containing glucose (YPD) or glycerol (YPG) as carbon source. YPD plates were incubated for 2 d, and YPG plates were incubated for 3 d at the indicated temperatures. (B) Wild-type (WT), ${Delta}$ mfb1, ${Delta}$ mdm30, and ${Delta}$ mfb1/ ${Delta}$ mdm30 ( ${Delta}$ ${Delta}$ ) cells expressing mitochondria-targeted GFP were grown to log phase in YPD or YPG medium and analyzed by DIC (left) and fluorescence (right) microscopy. Bar, 2 µm. (C) WT, cdc53, cdc34, and pre1 cells expressing mitochondria-targeted GFP were grown to log phase in YPD or YPG in the presence of doxycycline (+Dox) and analyzed as described above. Magnification is as in B.

To examine whether Mfb1 is required for normal mitochondrialdistribution and morphology, we performed a comprehensive analysisof mitochondria in cells lacking Mfb1 and/or Mdm30. Logarithmicallygrowing wild-type cells showed a characteristic tubular network,which is more ramified on the nonfermentable carbon source glycerolthan on the fermentable carbon source glucose (Figure 2B). Morethan 80% of the cells in ${Delta}$ mfb1, ${Delta}$ mdm30, and ${Delta}$ mfb1/ ${Delta}$ mdm30 culturesdisplayed aggregated mitochondria that were clumped togetherand deposited at random locations within the cells on glucose-containingmedium (Figure 2B and Table 1). In contrast, on the nonfermentablecarbon source glycerol, the majority of mutant cells containedfragmented mitochondria that were more or less evenly distributedin the cell (Figure 2B and Table 1). Because mitochondrial behaviorobserved by light microscopy seems very similar in ${Delta}$ mfb1 and ${Delta}$ mdm30 cells, we considered the possibility that Mfb1 and Mdm30function in related pathways and might have overlapping substratespecificity. Thus, we tested whether overexpression of one componentmight rescue the loss of the other. The MFB1 and MDM30 geneswere placed under control of the strong and inducible GAL1 promoterand expressed from a multicopy plasmid in wild type, ${Delta}$ mfb1, and ${Delta}$ mdm30 cells. Strains transformed with the empty vector servedas controls. ${Delta}$ mfb1 cells expressing the MFB1 gene from the GAL1promoter and ${Delta}$ mdm30 cells expressing the MDM30 gene from theGAL1 promoter showed wild-type–like mitochondria (Table 1),indicating that plasmid-expressed F-box proteins are functionaland suggesting that overexpression of these genes does not havenegative consequences for mitochondrial morphology. In contrast, ${Delta}$ mfb1 cells expressing the MDM30 gene from the GAL1 promoterand ${Delta}$ mdm30 cells expressing the MFB1 gene from the GAL1 promoterwere indiscernible from the vector controls (Table 1). Thissuggests that loss of one mitochondria-associated F-box proteincannot be compensated by overexpression of the other. We concludethat Mfb1 and Mdm30 are both required for maintenance of a wild-type–likemitochondrial reticulum and that they have nonredundant functions.

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Table 1. Mitochondrial phenotypes during vegetative growth

The F-box comprises a conserved binding site for Skp1 (Willemset al., 2004

; Petroski and Deshaies, 2005

). To test whetherthe presence of an intact F-box is essential for the proteins’functions, we overexpressed truncated Mfb1 and Mdm30 proteinslacking their F-boxes from a CUP1 promoter (MFB1 ${Delta}$ Fbox and MDM30 ${Delta}$ Fbox).Surprisingly, these constructs rescued the mitochondrial morphologydefects of the null mutants to a large extent (Table 1), suggestingthat at least some of the proteins’ functions in mitochondrialdynamics do not require assembly into SCF complexes. It shouldbe noted, however, that complementation of the mitochondrialphenotypes was seen under conditions that involved overexpressionof the ${Delta}$ F-box constructs from a strong promoter. Under theseconditions, truncated, nonfunctional F-box proteins might bestill able to bind to accumulated substrate proteins, such asFzo1. Even though we consider it unlikely, we cannot excludethe possibility that this binding might inactivate excess Fzo1,or other substrate proteins, and thereby restore normal mitochondrialmorphology in an indirect manner.

Several lines of evidence assign an important role to the ubiquitin/26Sproteasome system in mitochondrial morphogenesis. For example,overexpression of a mutant ubiquitin variant unable to formpolyubiquitin chains results in aberrant mitochondrial morphology(Fisk and Yaffe, 1999), and cells lacking functional proteasomesubunits have severe mitochondrial defects (Rinaldi et al.,1998; Altmann and Westermann, 2005). However, the exact roleof the proteasome in mitochondrial biogenesis is still unclear.We asked whether the mitochondrial phenotypes seen in F-boxprotein mutants resemble mitochondria in cells after depletionof Cdc53/Cullin and Cdc34, essential core components of SCFubiquitin ligases, or Pre1, an essential subunit of the 20Sproteasome core particle. Yeast mutants containing the CDC53,CDC34, or PRE1 gene under control of a promoter that can beshut off by the addition of doxycycline to the medium (Mnaimnehet al., 2004) were grown under inducing and repressing conditionson fermentable and nonfermentable carbon sources, and mitochondrialmorphology was analyzed. Mitochondria were fragmented in cdc53cells under all conditions and in pre1 and cdc34 cells underrepressing conditions on either carbon source (Figure 2C). Surprisingly,aggregated mitochondria, the major phenotypic class seen inmutants lacking mitochondria-associated F-box proteins grownon YPD medium, could only very rarely be observed in cdc53,cdc34, and pre1 mutants (Figure 2C and Table 1). Thus, mitochondrialdefects are clearly distinguishable in cdc53, cdc34, and pre1mutants on the one hand and mfb1 and mdm30 mutants on the otherhand. Together, our observations point to the involvement ofother, yet unidentified factors, in F-box protein-dependentregulation of mitochondrial dynamics.

Mfb1 and Mdm30 Are the Only F-box Proteins Required for Maintenance of Mitochondrial Morphology
The yeast genome contains 21 genes potentially encoding F-boxproteins (Willems et al., 2004). We asked whether in additionto MFB1 and MDM30 any of the remaining 19 genes is requiredfor normal mitochondrial distribution and morphology. Mitochondriawere stained with mitochondria-targeted GFP and examined byfluorescence microscopy in the following deletion mutants lackingnonessential genes: ${Delta}$ amn1, ${Delta}$ cos111, ${Delta}$ dia2, ${Delta}$ ela1, ${Delta}$ grr1, ${Delta}$ hrt3, ${Delta}$ rcy1, ${Delta}$ skp2, ${Delta}$ ufo1, ${Delta}$ ybr280c, ${Delta}$ ydr131c, ${Delta}$ ydr306c, ${Delta}$ yjl149w, ${Delta}$ ylr224w, ${Delta}$ ylr352w,and ${Delta}$ ymr258c. Three genes encoding F-box proteins, CDC4, CFT13,and MET30, are essential for viability in yeast. Mitochondrialmorphology was analyzed in strains carrying these genes undercontrol of a doxycycline-repressible promoter (Mnaimneh et al.,2004). All of these mutant strains lacking F-box proteins showedwild-type–like mitochondria (Table 2and Supplemental Figure 1).We conclude that Mfb1 and Mdm30 are the only members of theF-box protein family that are essential for maintenance of normalmitochondrial morphology in yeast.

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Table 2. Role of yeast F-box proteins in mitochondrial morphology

To examine whether deletion of the MFB1 gene has pleiotropiceffects on the morphology of other intracellular structureswe analyzed vacuoles, ER, and filamentous actin by fluorescencemicroscopy of wild-type and ${Delta}$ mfb1 cells. Because these cellularstructures seemed normal in ${Delta}$ mfb1 (Supplemental Figure 2) and ${Delta}$ mdm30 cells (Fritz et al., 2003

), we conclude that organellarmorphology defects in ${Delta}$ mfb1 and ${Delta}$ mdm30 mutants primarily affectmitochondria.

Mfb1 Is Not Required for Mitochondrial Fusion and Turnover of Fzo1
Mitochondrial fusion is blocked in ${Delta}$ mdm30 cells, presumably becausethe turnover of Fzo1 is inhibited and surplus Fzo1 protein accumulatesin the cell (Fritz et al., 2003). To test whether Mfb1 is requiredfor mitochondrial fusion, we assayed fusion by mating haploidcells of opposite mating types preloaded with different fluorescentmitochondrial matrix markers. At least 20 zygotes were analyzedper strain. Fluorescent labels immediately intermixed in 100%of the zygotes, indicating efficient mitochondrial fusion andcontent mixing both in wild-type and ${Delta}$ mfb1 cells (Figure 3A).Consistent with this finding, the steady-state level of Fzo1in vegetatively growing cells is not elevated in ${Delta}$ mfb1 cellsin comparison with the wild type, and deletion of the MFB1 genein the ${Delta}$ mdm30 mutant does not elevate Fzo1 levels further incomparison with the ${Delta}$ mdm30 single mutant (Figure 3B). We concludethat Mfb1 is not required for mitochondrial fusion or turnoverof Fzo1 during vegetative growth.

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Figure 3. Mfb1 is not required for mitochondrial fusion or turnover of Fzo1. (A) WT or ${Delta}$ mfb1 cells of opposite mating types containing mitochondria preloaded with GFP (mtGFP) or DsRed (mtDsRed) were mated, and zygotes were analyzed by fluorescence and DIC microscopy. DsRed fluorescence was analyzed first to avoid photoconversion of GFP. Bar, 5 µm. (B) WT, ${Delta}$ mfb1, ${Delta}$ mdm30, and ${Delta}$ mfb1/ ${Delta}$ mdm30 cells were grown to log phase in YPD medium. Steady-state concentrations of Fzo1 in total cell extracts were analyzed by immunoblotting using Fzo1-specific antibodies ( ${alpha}$ Fzo1). A cross-reacting protein (CR), which is invariantly expressed in all four strains, served as a loading control. (C) WT, ${Delta}$ mfb1, and ${Delta}$ mdm30 cultures were treated for the indicated time periods with mating pheromone ${alpha}$ factor. Turnover of Fzo1 was analyzed by immunoblotting of total cell extracts as in B.

Interestingly, Neutzner and Youle (2005)

reported that Mdm30is not required for proteasome-dependent degradation of Fzo1after G₁ cell cycle arrest evoked by treatment of yeast wild-typecells with the mating pheromone ${alpha}$ factor. These findings weregenetically confirmed using yeast strains carrying mutationsin genes encoding proteasome subunits (Escobar-Henriques etal., 2006

). We considered the possibility that in G₁ cell cycle-arrestedcells Mfb1 might serve as an alternative F-box protein to targetFzo1 to degradation. To test this, wild-type, ${Delta}$ mfb1, and ${Delta}$ mdm30cells were treated for different times with ${alpha}$ factor, and turnoverof Fzo1 was assayed by immunoblotting of cell extracts. Consistentwith previous findings, we observed efficient degradation ofFzo1 in ${alpha}$ factor-treated wild-type and ${Delta}$ mdm30 cells. However,efficient turnover of Fzo1 was also observed in ${Delta}$ mfb1 cells (Figure 3C).Hence, degradation of Fzo1 after mating pheromone-induced cellcycle arrest depends neither on Mdm30 nor on Mfb1.

Recruitment of Mdm30 to Mitochondria Is Independent of Fzo1
A major fraction of Mdm30 is associated with mitochondria (Fritzet al., 2003), and Mdm30 physically interacts with Fzo1 in anF-box–independent manner (Escobar-Henriques et al., 2006).Intriguingly, deletion of the MDM30 gene in a ${Delta}$ fzo1 backgroundproduces a synthetic growth defect, suggesting that Mdm30 mayhave other yet unknown target proteins in addition to Fzo1 (Fritzet al., 2003). To examine whether Mdm30 binds to mitochondriain the absence of its known binding partner, Fzo1, we fractionated ${Delta}$ fzo1 cells expressing FLAG-tagged Mdm30 (Mdm30^FLAG) and FLAG-taggedMdm30 lacking the F-box ( ${Delta}$ F-box^FLAG). On fractionation of yeastcells, we observed that Mdm30 cofractionated with mitochondria,even in the absence of Fzo1 (Figure 4). This suggests that Mdm30has one or more mitochondrial binding partners in addition toFzo1 and thus may have multiple target proteins on mitochondria.

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Figure 4. Binding of Mdm30 to mitochondria does not require Fzo1. Wild-type (FZO1) and ${Delta}$ fzo1 strains were transformed with plasmids expressing N-terminally FLAG-tagged full-length Mdm30 (Mdm30^FLAG) and Mdm30 lacking its F-box ( ${Delta}$ F-box^FLAG) from the CUP1 promoter. Total cell extracts (T) and subcellular fractions were prepared from logarithmically growing cultures. Crude mitochondria contained in the pellet fraction (P) and cytosolic proteins contained in the supernatant (S) were isolated by differential centrifugation and analyzed by immunoblotting using antibodies against the FLAG epitope, the mitochondrial protein Tom40, and the cytosolic protein triose phosphate isomerase Tpi1.

Ultrastructure of Cells Lacking Mfb1 and Mdm30
Next, we examined the ultrastructure of wild-type, ${Delta}$ mfb1, ${Delta}$ mdm30,and ${Delta}$ mfb1/ ${Delta}$ mdm30 cells by electron microscopy. To obtain high-resolutionimages of the three-dimensional organization of mitochondria,we prepared serial ultrathin sections (70 nm), analyzed themby transmission electron microscopy, and generated three-dimensionalmodels (Figure 5, A and B). Although aggregated and clumpedmitochondria of cells grown in glucose-containing medium lookedvery similar in all three mutant strains when observed by fluorescencemicroscopy (compare Figure 2B and Table 1), electron microscopicanalyses revealed striking differences. When the three-dimensionalstructure of mitochondria was reconstructed from 31 consecutivesections (corresponding to ${approx}$ 2170 nm) of a wild-type cell, threemorphologically distinct organelles were observed within thisvolume (Figure 5A). After three-dimensional reconstruction of27 sections (corresponding to ${approx}$ 1890 nm) of a ${Delta}$ mfb1 cell, we foundthat all mitochondria within this volume were interconnectedand formed one closed continuum consisting of clumped tubules(Figure 5A). In contrast, three-dimensional reconstruction of30 sections (corresponding to ${approx}$ 2100 nm) of a ${Delta}$ mdm30 cell revealedan aggregate of seven distinct organelles, and 18 sections (correspondingto ${approx}$ 1260 nm) of a ${Delta}$ mfb1/ ${Delta}$ mdm30 cell contained 16 small and morphologicallyseparable organelles (Figure 5A). These analyses were repeatedwith at least one additional cell for each strain, yieldingvery similar results (our unpublished observations). All cellswere harvested from logarithmically growing cultures, and foreach strain at least one cell that clearly carried a bud wasanalyzed.

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Figure 5. Ultrastructure of cells lacking Mfb1 or Mdm30. (A) WT, ${Delta}$ mfb1, ${Delta}$ mdm30, and ${Delta}$ mfb1/ ${Delta}$ mdm30 cells were grown to log phase in YPD medium, fixed with glutaraldehyde, treated with zymolyase to remove the cell wall, postfixed with osmium tetroxide, and en bloc stained with uranyl acetate. After embedding in Spurr’s resin, serial ultrathin sections (70 nm) were prepared and analyzed by transmission electron microscopy. The three-dimensional structure of mitochondria was reconstructed using IMOD software (Kremer et al., 1996

). Morphologically separate organelles are displayed in different colors. The contour of the plasma membrane is shown by a white line for each section. The model of the wild-type cell was reconstructed from 31 consecutive sections, the ${Delta}$ mfb1 cell from 27 sections, the ${Delta}$ mdm30 cell from 30 sections, and the ${Delta}$ mfb1/ ${Delta}$ mdm30 cell from 18 sections. (B) Three representative consecutive sections that were used for reconstruction of the three-dimensional models displayed in A. (C) Enlarged detail of a transmission electron micrograph of a ${Delta}$ mfb1/ ${Delta}$ mdm30 cell (taken from the third section displayed in B). White arrows point to close contacts between morphologically separate nonfused mitochondria. It should be noted that yeast strains related to BY4743 generally contain only few cristae on glucose-containing medium. However, strains lacking Mfb1 or Mdm30 are able to form normal cristae (not visible here).

Intriguingly, mitochondria in ${Delta}$ mdm30 (our unpublished data) and ${Delta}$ mfb1/ ${Delta}$ mdm30 cells (Figure 5C) were sometimes observed to be inclose contact without fusion. This phenotype resembles clusteredmitochondria seen in mammalian cells overexpressing Fzo1 homologuesMfn2 (Rojo et al., 2002

) or Mfn1 (Santel et al., 2003

). It isconceivable that surplus Fzo1 forms nonfunctional fusion complexesin strains lacking Mdm30. These complexes might tether neighboringorganelles, as it has been observed for mammalian cells expressingmutant forms of Mfn2 (Eura et al., 2003

) or truncated formsof Mfn1 (Koshiba et al., 2004

). Interestingly, some electron-densematerial is seen in the contact areas (Figure 5C, arrows), whichmight consist of accumulated Fzo1. A block of mitochondrialfusion in cells lacking Mdm30 leads to fragmentation of mitochondriaby ongoing fission (Fritz et al., 2003

). Because fusion is notblocked in ${Delta}$ mfb1 cells, mitochondria may fuse and form a continuumin cells lacking Mfb1 as long as Mdm30 is present. We concludethat mitochondrial aggregates are formed by different mechanismsin cells lacking Mfb1 and Mdm30.

Tubular, aggregated mitochondria in ${Delta}$ mfb1 cells that were clearlydifferent from fragmented, aggregated mitochondria in ${Delta}$ mdm30cells were also observed by Kondo-Okamoto et al. (2006). Itshould be noted that these researchers found that short tubulesin ${Delta}$ mfb1 cells were less interconnected in the W303 genetic backgroundthan the structures we observed in BY4741-related ${Delta}$ mfb1 strains.We consider it likely that these differences are due to strain-specificeffects.

Mdm30 Is Required for Remodeling of Mitochondria during Sporulation
Mitochondria undergo extensive remodeling during sporulation(Miyakawa et al., 1984; Gorsich and Shaw, 2004). Interestingly,the MFB1 and MDM30 genes are induced during sporulation (Chuet al., 1998), raising the intriguing possibility that mitochondria-associatedF-box proteins are required for progression through the mitochondrialremodeling program during meiosis and spore formation. To testthis, we observed mitochondrial behavior during sporulationin diploid wild-type cells and homozygous diploid cells lackingMfb1 or Mdm30. The tubular mitochondrial network of logarithmicallygrowing wild-type cells fragments upon entry into stationaryphase. Mitochondrial fragments fuse again in pretetrads to builda complex tubular network. Tubular mitochondria are then partitionedto the newly formed spores in early tetrads and fragment onceagain in late tetrads (Miyakawa et al., 1984; Gorsich and Shaw,2004; Figure 6A and Table 3). Although the behavior of mitochondriaduring sporulation is virtually identical in wild-type cellsand cells lacking Mfb1, formation of a tubular mitochondrialnetwork in pretetrads is blocked in the absence of Mdm30, andmitochondria remain fragmented throughout the entire sporulationprocess (Figure 6A and Table 3).

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Figure 6. Mdm30 is required for mitochondrial remodeling and inheritance during sporulation. (A) Homozygous diploid WT, ${Delta}$ mfb1 and ${Delta}$ mdm30 cells expressing mitochondria-targeted GFP were grown to log phase (top) in YPD medium. To induce sporulation, strains were grown to stationary phase on YPD plates, transferred to sporulation medium, and incubated at 30°C for 12 d. At each stage of sporulation, representative cells were analyzed by fluorescence and DIC microscopy, as in Figure 2B. Right is a merged image of DIC and fluorescence micrographs. Mitochondrial inheritance defects were observed in early and late tetrads. Ascospores devoid of mitochondria are marked with an asterisk. Bar, 2 µm. (B) Percentage of asci is indicated that contained at least one spore devoid of mitochondria at the early or late tetrad stage (number of asci scored: WT, 413; ${Delta}$ mfb1, 422; and ${Delta}$ mdm30, 264). (C) Percentage of cells is indicated that had formed asci with two to four spores at the late tetrad stage (number of cells scored: 400 for each strain).

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Table 3. Mitochondrial phenotypes during sporulation

We asked whether the aberrant behavior of mitochondria in homozygousdiploid ${Delta}$ mdm30 cells would result in a mitochondrial inheritancedefect. To test this, spores devoid of mitochondria (Figure 6A,bottom) were counted in early and late tetrads. In wild-typecells, 6.5% of asci contained at least one spore without anyvisible mitochondrion. This number was slightly increased to10.4% in ${Delta}$ mfb1 asci. Interestingly, the mitochondrial inheritancedefect was much more severe in ${Delta}$ mdm30 asci, where 23.1% of theasci contained one or more spores devoid of mitochondria (Figure 6B).At the same time, sporulation efficiency was decreased in cellslacking Mdm30. Although 15.3% of wild-type cells and 15.8% ofhomozygous diploid ${Delta}$ mfb1 cells formed tetrads, only 5.3% of homozygousdiploid ${Delta}$ mdm30 cells formed asci (Figure 6C). We conclude thatMdm30-dependent remodeling of mitochondria is important formitochondrial inheritance during sporulation.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Even in a simple unicellular organism, such as yeast, mitochondriashow a complex behavior. Volume, number, and morphology of mitochondriaare readily adapted to the carbon source of the growth mediumand oxygen supply (Stevens, 1981; Visser et al., 1995; Egneret al., 2002; Jakobs et al., 2003). During mitotic growth, mating,and sporulation, mitochondria are partitioned to newly formedcells by highly ordered inheritance mechanisms and dynamic remodelingprocesses (Miyakawa et al., 1984; Nunnari et al., 1997; Simonet al., 1997; Okamoto et al., 1998; Yang et al., 1999; Gorsichand Shaw, 2004). How are mitochondrial fusion and fission orchestratedduring these events?

The complement of F-box proteins that is present in every eukaryoticcell is thought to have sweeping regulatory powers by virtueof its ability to directly link SCF substrates to signalingpathways (Willems et al., 2004). Consistently, our results assigna key role to F-box proteins in regulating mitochondrial dynamics.Mfb1 and Mdm30 are both required for proper mitochondrial distributionand morphology during mitotic growth. A comprehensive analysisof mutants of all known yeast F-box protein-encoding genes suggeststhat the remaining 19 members of this protein family are dispensablefor maintenance of wild-type–like mitochondria. Consistentwith this finding, large-scale analysis of protein localizationin yeast (Huh et al., 2003) and analysis of the mitochondrialproteome (Sickmann et al., 2003) did not reveal any other mitochondria-associatedF-box protein. Genetic and morphological evidence suggests thatMfb1 and Mdm30 function independently of each other and mayhave different target proteins. A ${Delta}$ mfb1/ ${Delta}$ mdm30 double mutant doesnot show a more severe phenotype than a ${Delta}$ mdm30 single mutant;overexpression of one F-box protein does not compensate forthe loss of the other; and deletion of the MDM30 gene leadsto a block in fusion, whereas deletion of the MFB1 gene leadsto clumped interconnected mitochondria. In addition to theirrole during mitotic growth, mitochondria-associated F-box proteinsare important for mitochondrial dynamics during the executionof cell developmental programs. Consistent with a role in mitochondrialdynamics during development, both genes are several-fold inducedduring sporulation (Chu et al., 1998). Although a role of Mfb1in regulating mitochondrial behavior during meiosis is stillunknown, we consider it likely that Mdm30 modulates mitochondrialfusion activity because fusion of fragmented mitochondria toa tubular network is blocked in pretetrads lacking Mdm30 (Figure 6A).Because Mdm30 is also required for fusion of mitochondria duringmating (Fritz et al., 2003), F-box proteins play an importantrole in mitochondrial dynamics throughout the entire life cycleof budding yeast.

A synthetic growth defect in ${Delta}$ fzo1/ ${Delta}$ mdm30 double mutants (Fritzet al., 2003) and Fzo1-independent binding of Mdm30 to mitochondria(Figure 4) suggest that Mdm30 may have other yet unknown mitochondrialtarget proteins in addition to Fzo1. Interestingly, it has recentlybeen reported that Mdm30 is a transcriptional coactivator ofGal4. This activity has been proposed to be required for activationof Gal4 target genes and growth on synthetic galactose medium(Muratani et al., 2005). However, we and others observed that ${Delta}$ mdm30 mutants are able to grow on galactose-containing media(Okamoto and Shaw, 2005), and mitochondria-targeted fluorescentproteins are efficiently expressed from the GAL1 promoter in ${Delta}$ mdm30 strains (Fritz et al., 2003). Thus, it is not clear whetherMdm30 is of general importance for expression of Gal4-dependentgenes, and possible additional target proteins of mitochondria-associatedF-box proteins remain to be identified.

Numerous lines of evidence point to an important role of theubiquitin/26S proteasome system in mitochondrial biogenesis.Yeast mutants lacking functional subunits of ubiquitin ligasesor the proteasome harbor aberrant mitochondria (Rinaldi et al.,1998; Fisk and Yaffe, 1999; Altmann and Westermann, 2005), andproteasome inhibitors (Neutzner and Youle, 2005) and mutationsin proteasome subunit-encoding genes (Escobar-Henriques et al.,2006) reduce the rate of degradation of Fzo1 in ${alpha}$ factor-arrestedcells. Consistent with a specific role of ubiquitylation ofmitochondrial proteins, the mitochondrial outer membrane harborsa deubiquitinating enzyme, Ubp16. However, neither deletionnor overexpression of the UBP16 gene produces any obvious phenotype,and mitochondrial morphology and inheritance are not affectedin ubp16 mutants (Kinner and Kölling, 2003). What mightbe the role of Mfb1 and Mdm30 in mediating turnover of Fzo1and other mitochondrial target proteins? Mdm30 has been shownto interact with Skp1 and Cdc53 in the yeast two-hybrid system(Uetz et al., 2000), recombinant Mdm30 assembles with Skp1,Cdc53, and Rbx1 into an SCF complex in vitro (Kus et al., 2004),and Mfb1 has been found in a complex with Skp1 in large-scaleidentification of yeast protein complexes by mass spectrometry(Ho et al., 2002) and in coimmunoprecipitation experiments (Kondo-Okamotoet al., 2006). However, Mfb1–Skp1 complexes apparentlydo not contain Cdc53 (Kondo-Okamoto et al., 2006). Intriguingly,we observed that the mitochondrial phenotype of yeast strainslacking Mfb1 and Mdm30 cannot be mimicked by depletion of SCFcore complex or proteasome subunits and that the F-box motifof Mfb1 and Mdm30 is not essential for rescue of the mitochondrialmorphology defect of the null mutants. Furthermore, proteasome-dependentdegradation of Fzo1 in ${alpha}$ factor-arrested cells does not requireMdm30 (Neutzner and Youle, 2005) or Mfb1 (Figure 3C), and Mdm30-mediatedturnover of Fzo1 in vegetatively growing cells is independentof the proteasome (Escobar-Henriques et al., 2006). Thus, itseems that mitochondria-associated F-box proteins do not actas bona fide SCF ubiquitin ligases. Rather, they may exert atleast some of their functions independently of the proteasome,as it has been demonstrated for Rcy1, an F-box protein involvedin regulation of vesicular trafficking (Galan et al., 2001).Apparently, Mfb1 and Mdm30 are two important components of acomplex network of substrate recognition factors and proteolyticsystems mediating turnover of mitochondrial proteins. Many,yet unknown, factors remain to be identified.

ACKNOWLEDGMENTS

We are grateful to Rita Grotjahn and Annette Suske for technicalsupport and Koji Okamoto for communicating results before publication.This work was supported by grants of the Deutsche Forschungsgemeinschaftto B. W. (We 2174/2-4 and 4-1) and T. L. (SFB 635/P18) and anEuropean Molecular Biology Organization fellowship to M.E.-H.

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.E06-01-0053)on June 21, 2006.

Address correspondence to: Benedikt Westermann (benedikt. westermann{at}uni-bayreuth.de)

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