Prohibitins Regulate Membrane Protein Degradation by the m-AAA Protease in Mitochondria

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Molecular and Cellular Biology, May 1999, p. 3435-3442, Vol. 19, No. 5
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Prohibitins Regulate Membrane Protein Degradation by the m-AAA Protease in Mitochondria

Gregor Steglich, Walter Neupert, and Thomas Langer^*

Institut für Physiologische Chemie der Universität München, 80336 Munich, Germany

Received 9 December 1998/Returned for modification 21 January 1998/Accepted 30 January 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Prohibitins comprise a protein family in eukaryotic cells with potential roles in senescence and tumor suppression. Phb1pand Phb2p, members of the prohibitin family in Saccharomyces cerevisiae,have been implicated in the regulation of the replicative lifespan of the cells and in the maintenance of mitochondrial morphology.The functional activities of these proteins, however, have notbeen elucidated. We demonstrate here that prohibitins regulatethe turnover of membrane proteins by the m-AAA protease, a conservedATP-dependent protease in the inner membrane of mitochondria.The m-AAA protease is composed of the homologous subunits Yta10p(Afg3p) and Yta12p (Rca1p). Deletion of PHB1 or PHB2 impairs growthof $Delta$ yta10 or $Delta$ yta12 cells but does not affect cell growth in thepresence of the m-AAA protease. A prohibitin complex with a nativemolecular mass of approximately 2 MDa containing Phb1p and Phb2pforms a supercomplex with the m-AAA protease. Proteolysis of nonassembledinner membrane proteins by the m-AAA protease is accelerated inmitochondria lacking Phb1p or Phb2p, indicating a negative regulatoryeffect of prohibitins on m-AAA protease activity. These resultsfunctionally link members of two conserved protein families ineukaryotes to the degradation of membrane proteins inmitochondria.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

The mechanisms which underlie the turnover of membrane proteins in the cell remain poorly understood. Various plasma membraneproteins are internalized in a ubiquitin-dependent manner anddegraded in lysosomes and vacuoles (14). Proteolysis of membraneproteins of the endoplasmic reticulum requires their retrogradetransport to the cytosol and proceeds via the cytoplasmic ubiquitin-proteasomepathway (5, 30). Another proteolytic system has emerged fromstudies on the turnover of mitochondrial inner membrane proteins.Proteolysis is mediated by membrane-embedded ATP-dependent AAAproteases, which comprise a conserved protein family with homologuesin various organisms, including bacteria, plants, yeasts and humans(18, 28, 31).

Two AAA proteases have been identified in the mitochondrial inner membrane of Saccharomyces cerevisiae (11, 26, 34,35). Both proteases are composed of homologous subunits andform high-molecular-mass complexes of approximately 1 MDa (3,20). Their catalytic sites, however, are exposed to oppositemembrane surfaces: the m-AAA protease containing Yta10p (Afg3p)and Yta12p (Rca1p) acts on the matrix side, while the i-AAA proteasecontaining Yme1p is active in the intermembrane space (3, 20).In S. cerevisiae, AAA proteases fulfill crucial roles in mitochondrialbiogenesis. Deletion of YME1 impairs the respiratory competenceof the cells at high temperature and results in changes in themorphology of mitochondria (6, 34). Cells lacking Yta10por Yta12p, on the other hand, lose respiratory competence andexhibit deficiencies in the assembly of the F₁F₀-ATP synthaseand respiratory chain complexes in the inner membrane (11, 27,32, 35). The m-AAA protease controls the expression of theintron-containing mitochondrial genes COB and COX1, affectingthe splicing of the respective pre-mRNAs (2). In addition,evidence is accumulating for posttranslational functions of them-AAA protease during the biogenesis of the respiratory chain(2, 27). Mutations in a human homologue of Yta10p and Yta12p,paraplegin, have recently been reported to cause a hereditaryform of spastic paraplegia, pointing to important functions ofAAA proteases also in higher eukaryotes (7).

Prohibitin was originally identified in mammalian cells for its decreased expression in tumor cells and for its ability tonegatively regulate cell proliferation (21, 25). Subsequentstudies established that prohibitin belongs to a ubiquitous proteinfamily in eukaryotes which is highly conserved from yeast to human(9). In eukaryotic cells there are two homologues which wereinitially found in association with the plasma membrane in B lymphocytes(33) but later localized to the inner membrane of mitochondriain various cell types (4, 8, 15). The S. cerevisiae prohibitinhomologues Phb1p and Phb2p have been implicated in the regulationof the replicative life span of the cells (4, 8). Moreover,the observation of a genetic interaction of PHB1 or PHB2 withmitochondrial inheritance components points to a role for themaintenance of mitochondrial morphology (4). The function ofprohibitins on the molecular level, however, isunknown.

Here we describe a role of the prohibitin family members Phb1p and Phb2p of S. cerevisiae for the degradation of membraneproteins by the m-AAA protease. Phb1p and Phb2p are anchored tothe mitochondrial inner membrane via an N-terminal transmembranesegment and expose their C termini to the intermembrane space.They form a high-molecular-mass complex of approximately 2 MDawhich physically interacts with the m-AAA protease but not withthe homologous i-AAA protease. Proteolysis of nonassembled Cox3pand Atp6p by the m-AAA protease proceeds at an increased ratein mitochondria lacking Phb1p or Phb2p, suggesting an inhibitoryeffect of prohibitins on m-AAA proteaseactivity.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Yeast strains and growth conditions. Yeast strains used in this study are derivatives of W303. Cells were grown at 30°C on YP medium (1% yeast extract, 2% peptone)containing 2% glucose or, for isolation of mitochondria, 2% galactoseand 0.5%lactate.

$Delta$ yta10 (YHA101), $Delta$ yta12 (YHA201), and $Delta$ yme1 strains were described previously (2, 20). PHB1 and PHB2 were disrupted inwild-type, $Delta$ yta10, $Delta$ yta12, and $Delta$ yme1 cells by PCR-targeted homologousrecombination (36) using the heterologous marker HIS3MX6 ( $Delta$ phb1[YGS410], $Delta$ phb1 $Delta$ yta10 [YGS404], and $Delta$ phb1 $Delta$ yme1 [YGS406]) orKanMX4 ( $Delta$ phb1 $Delta$ yta12 [YGS416], $Delta$ phb2 [YGS501], $Delta$ phb2 $Delta$ yta10 [YGS504], $Delta$ phb2 $Delta$ yme1 [YGS505], and $Delta$ phb2 $Delta$ yta12 [YGS506]). The completeopen reading frames of PHB1 or PHB2 were replaced by the disruptioncassettes. COX4 was disrupted in W303 by homologous recombinationusing the auxotrophic marker TRP1. PHB1 and PHB2 were deletedin $Delta$ cox4 and $Delta$ atp10 cells (1) by PCR-targeted homologous recombinationusing the heterologous markers HIS3MX6 and KanMX4, respectively(36). Homologous recombination was verified in each case byPCR.

Gel filtration analysis. Mitochondria were isolated from wild-type, $Delta$ phb1, and $Delta$ yta10 cells as described previously (13, 37) and resuspended (0.4mg) at a concentration of 1 mg/ml in buffer A (phosphate-bufferedsaline [pH 7.4], 10% glycerol, 1 mM ATP, 4 mM magnesium acetate,0.5 mM phenylmethylsulfonyl fluoride) containing 1% digitoninor 0.2% Triton X-100 as indicated. After incubation for 30 minat 4°C under vigorous mixing, mitochondrial extracts were centrifugedfor 20 min at 109,000 × g. The supernatant was analyzed by fastprotein liquid chromatography using a Superose 6 column equilibratedwith buffer A containing 1% digitonin or 0.2% Triton X-100 (flowrate, 0.3 ml/min). Fractions of 0.5 or 0.25 ml were collectedas indicated, precipitated with trichloroacetic acid (12.5%),and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis(SDS-PAGE). Yta10p, Yta12p, Phb1p, and Phb2p were detected inthe eluate by immunostaining using a chemiluminescence detectionsystem. Protein amounts were determined by laser densitometryand are given as percentage of the specified protein in theeluate.

Coimmunoprecipitation experiments. Mitochondria were isolated from the strains indicated and lysed as described for the gel filtration experiments, using bufferA containing 0.2% Triton X-100. Virtually identical results wereobtained in the presence of 1% digitonin. After lysis, an aliquotwas withdrawn from the supernatant for control. Supernatants wereincubated under gentle shaking for 60 min at 4°C with preimmuneor antiserum directed against Phb1p, Phb2p, Yta10p, Yta12p, orYme1p as indicated. Each serum had been coupled to protein A-Sepharose.The beads were then washed three times with buffer A. The immunocomplexeswere dissociated in SDS sample buffer by vigorous shaking for10 min at room temperature and incubated for 3 min at 95°C. Precipitatedproteins and control preparations were analyzed by SDS-PAGE andimmunostaining.

Determination of the topology of Phb1p and Phb2p in the inner membrane. Mitochondria were resuspended in buffer B (50 mM HEPES-KOH [pH 7.2], 0.75% bovine serum albumin, 0.5 M sorbitol, 80 mM KCl,2.5 mM magnesium acetate, 1 mM potassium phosphate, 0.5 mM MnCl₂)at a concentration of 100 µg/ml or, for osmotic disruption ofthe outer membrane (swelling), in buffer C (20 mM HEPES-KOH [pH7.4], 0.3% bovine serum albumin, 50 mM sorbitol, 8 mM KCl, 1 mMmagnesium acetate, 0.8 mM potassium phosphate, 0.2 mM MnCl₂) ata concentration of 40 µg/ml. Samples were supplemented with proteinaseK (100 µg/ml) or trypsin (100 µg/ml) when indicated and incubatedfor 30 min at 4°C. The proteases were inhibited by incubatingthe samples for 3 min at 4°C in the presence of phenylmethylsulfonylfluoride (0.5 mM) or a 20-fold molar excess of soybean trypsininhibitor, respectively. Mitochondrial fractions were analyzedby SDS-PAGE and immunostaining using antisera directed againstPhb1p, Phb2p, D-lactate dehydrogenase, andMge1p.

Labeling of mitochondrial translation products in vivo. Mitochondrially encoded proteins were labeled in intact cells with [³⁵S]methionine in the presence of cycloheximide for 5 min at 30°Cas previously described (10, 19, 22). To examine the stabilityof newly synthesized polypeptides, unlabeled methionine was addedto a final concentration of 30 mM and cells were further incubatedat 30°C. Aliquots were withdrawn at the time points indicatedand analyzed by SDS-PAGE and fluorography. The amount of newlysynthesized proteins present in the cells was quantified witha phosphorimaging system. The kinetics of degradation were analyzedin logarithmic plots by assuming a simple first-orderreaction.

Generation of Phb1p- and Phb2p-specific antisera. To generate polyclonal antisera directed against Phb1p and Phb2p, 0.8-kb DNA fragments of PHB1 and PHB2, corresponding toamino acids 27 to 287 of Phb1p and to amino acids 61 to 315 ofPhb2p, respectively, were amplified by PCR. The fragments werecloned into the BamHI/PstI sites of the bacterial expression vectorpQE9 (Qiagen). After expression in Escherichia coli XL1-Blue,the proteins were purified according to standard procedures andused for generation of antibodies inrabbits.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

A high-molecular-mass complex in the inner membrane containing m-AAA protease and prohibitins. Upon determination of the native molecular mass of the m-AAA protease by gel filtration, strikingly different results wereobtained in the presence of different detergents: when mitochondrialmembranes were extracted with digitonin, the m-AAA protease subunitsYta10p and Yta12p eluted from the column in a single peak whichcorresponded to a molecular mass greater than 2 MDa (Fig. 1A).In contrast, after solubilization of mitochondria with the nonionicdetergent Triton X-100, both m-AAA protease subunits coelutedfrom the sizing column in fractions corresponding to a nativemolecular mass of approximately 1 MDa as reported previously (Fig.1B) (3). These results suggest that Yta10p and Yta12p are partof a supercomplex with an unexpected large molecular mass whichremains stable when mitochondria are treated with the mild detergentdigitonin.

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FIG. 1. Cofractionation of Phb1p and Phb2p with the m-AAA protease upon sizing chromatography. Wild-type mitochondria were solubilized in buffer A containing 1% digitonin (A) or 0.2% Triton X-100 (B) as described in Materials and Methods. Extracts were fractionated by Superose 6 chromatography. Eluate fractions (0.5 ml) were analyzed by SDS-PAGE and immunostaining with antisera directed against Yta10p ( $black-triangle$ ), Yta12p ( $triangle$ ), Phb1p (

), and Phb2p ( $open circle$ ). Hsp60 (12.5 ml; arrow 1), thyroglobulin (13 ml; arrow 2), apoferritin (14 ml; arrow 3), alcohol dehydrogenase (15.5 ml; not shown) and bovine serum albumin (16.5 ml; not shown) were used for calibration.

In an attempt to identify other proteins which might interact with Yta10p and Yta12p, we examined the native molecular massof the prohibitin homologues Phb1p and Phb2p in the inner membrane.Eluate fractions of the gel filtration columns were analyzed byimmunostaining using Phb1p- and Phb2p-specific polyclonal antisera.Phb1p and Phb2p coeluted with Yta10p and Yta12p from the columnif mitochondrial extracts were fractionated by gel filtrationin the presence of digitonin (Fig. 1A). After solubilization ofmitochondria with Triton X-100, Phb1p and Phb2p also coelutedin a single peak which was only slightly shifted toward the lower-molecular-massregion (Fig. 1B). They eluted in fractions corresponding to anative molecular mass of approximately 2 MDa under these conditions.Nonassembled Phb1p and Phb2p, which have molecular masses of 31and 34 kDa, respectively, were not detectable in the eluate. Incontrast, peak fractions containing Yta10p and Yta12p were significantlyshifted toward a lower molecular mass after solubilization ofmitochondria with Triton X-100 (Fig. 1B).

The cofractionation of Phb1p and Phb2p with each other and with the m-AAA protease subunits Yta10p and Yta12p in the presenceof digitonin points to an interaction of these proteins. To furtherinvestigate this possibility, phb1- and phb2-null strains wereconstructed by disruption of the PHB1 and PHB2 genes, respectively.Notably, Phb1p was not detectable in $Delta$ phb2 cells by immunostaining,nor was Phb2p detectable in $Delta$ phb1 cells (data not shown) (4).The cellular levels of Yta10p and Yta12p were not altered by mutationsin PHB1 or PHB2 (data not shown). Mitochondria were isolated from $Delta$ phb1 cells and solubilized in digitonin, and extracts were analyzedby gel filtration. In contrast to wild-type mitochondria, Yta10pand Yta12p were exclusively detected in eluate fractions correspondingto a molecular mass of approximately 1 MDa (Fig. 2A). The assemblyof Yta10p and Yta12p was apparently not affected in $Delta$ phb1 mitochondria,but the formation of the larger complex depended on the presenceof Phb1p. Likewise, when the native molecular mass of prohibitinswas determined in digitonin extracts of $Delta$ yta10 mitochondria lackingm-AAA protease, Phb1p and Phb2p still coeluted from the column(Fig. 2B). The peak fractions, however, were slightly shiftedcompared to wild-type mitochondria, corresponding to a somewhatlower molecular mass of approximately 2 MDa (Fig. 2B).

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FIG. 2. Gel filtration analysis of mitochondrial extracts lacking prohibitins or m-AAA protease. (A) Wild-type (WT) and $Delta$ phb1 mitochondria or (B) wild-type (WT) and $Delta$ yta10 mitochondria were lysed in buffer A containing 1% digitonin and fractionated by sizing chromatography as described in Materials and Methods. In panel B, fractions of 0.25 ml were collected to increase the resolution. Eluate fractions were analyzed by SDS-PAGE and immunostaining with antisera directed against (A) Yta10p ( $black-triangle$ and

) and Yta12p ( $triangle$ and

) or (B) Phb1p (

and $black-down-triangle$ ) and Phb2p ( $open circle$ and $down-triangle$ ). Proteins used for calibration are described in the legend to Fig. 1.

Taken together, these results provide initial evidence for an interaction of the prohibitin homologues Phb1p and Phb2p withthe m-AAA protease subunits Yta10p and Yta12p. Moreover, we concludefrom these experiments that Phb1p and Phb2p have similar nativemolecular masses of approximately 2 MDa in the inner membraneregardless of the presence of the m-AAAprotease.

Interaction of a Phb1p-Phb2p complex with the m-AAA protease. To demonstrate a direct physical interaction of Phb1p and Phb2p with each other and with Yta10p and Yta12p in an unambiguousfashion, coimmunoprecipitation experiments were performed. Mitochondriawere solubilized and treated with a Yta10p- or Yta12p-specificantibody or preimmune serum (Fig. 3A). Yta10p and Yta12p werespecifically coprecipitated under these conditions (Fig. 3A),confirming their previously reported association as a complexof the inner membrane (3). Moreover, both Phb1p and Phb2p werecoprecipitated with antibodies directed against Yta10p and Yta12pbut not with preimmune serum (Fig. 3A). Precipitation of prohibitinswith the Yta10p- and Yta12p-specific antiserum was not observedin $Delta$ yta10 or $Delta$ yta12 mitochondria, respectively (Fig. 3A). Likewise,when the Phb1p- or Phb2p-specific antiserum was used for immunoprecipitation,Yta10p and Yta12p were present in the immunoprecipitates fromwild-type mitochondria but not from $Delta$ phb1 or $Delta$ phb2 mitochondria(Fig. 3B). Notably, Phb2p was coprecipitated with an antibodydirected against Phb1p, as was Phb1p with an antibody againstPhb2p under these conditions (Fig. 3B). These experiments establishcomplex formation of Phb1p and Phb2p with subunits of the m-AAAprotease in mitochondria and suggest that the two prohibitin homologuesinteract directly with each other. We also used a Yme1p-specificantiserum in these experiments to test for a possible associationof prohibitins with the i-AAA protease subunit Yme1p, which ishomologous to Yta10p and Yta12p (Fig. 3A). However, neither Phb1por Phb2p nor Yta10p or Yta12p was detected in the precipitateby Western blot analysis, indicating that prohibitins specificallyinteract with the m-AAA protease.

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FIG. 3. Coimmunoprecipitation of the m-AAA protease with the Phb1p-Phb2p complex. Mitochondria isolated from the indicated strains were solubilized and subjected to immunoprecipitation as described in Materials and Methods, using antisera directed against Yta10p, Yta12p, and Yme1p (A) or Phb1p and Phb2p (B) and the respective preimmune sera. The immunoprecipitates were analyzed by SDS-PAGE and immunostaining. WT, wild type.

Does the Phb1p-Phb2p complex interact only with the assembled m-AAA protease, or does it also bind to nonassembled Yta10pand Yta12p subunits? Nonassembled Yta10p or Yta12p subunits accumulatedat wild-type levels in mitochondria lacking Yta12p or Yta10p,respectively (data not shown). Therefore, coimmunoprecipitationexperiments with Phb1p- and Phb2p-specific antisera were performedwith detergent extracts derived from $Delta$ yta12 or $Delta$ yta10 mitochondria(Fig. 3B). In contrast to wild-type mitochondria, Yta12p was notprecipitated either with the Phb1p- or Phb2p-specific antiserumin $Delta$ yta10 mitochondria (Fig. 3B), nor was Yta10p precipitatedby either antibody in $Delta$ yta12 mitochondria (Fig. 3B). On the otherhand, deletion of YME1 did not affect the interaction of the prohibitinswith Yta10p and Yta12p (Fig. 3B). We conclude from these experimentsthat Phb1p and Phb2p interact only with the assembled m-AAA protease.It should also be noted that neither the coprecipitation of Phb2pwith the Phb1p-specific antibody nor the coprecipitation of Phb1pwith the Phb2p-specific antibody was affected in the absence ofYta10p and Yta12p (Fig. 3B). This observation is in agreementwith the observed cofractionation of both prohibitins as a high-molecular-weightcomplex upon sizing chromatography under these conditions (Fig.2B).

Topology of Phb1p and Phb2p in the inner membrane. Phb1p and Phb2p both contain single hydrophobic stretches at their N termini which may serve as membrane-spanning segments.Submitochondrial fractionation identified Phb1p and Phb2p as integralcomponents of the mitochondrial inner membrane (data not shown)(4). After osmotic disruption of the outer membrane, Phb1pand Phb2p were accessible to trypsin when added at high concentrations(Fig. 4). The protease sensitivity is shared with D-lactate dehydrogenase,an inner membrane protein with a large domain exposed to the intermembranespace (Fig. 4) (29). The matrix protein Mge1p, on the otherhand, was not accessible to the protease under these conditions(Fig. 4). These results indicate that an N-terminal domain anchorsPhb1p and Phb2p to the inner membrane, while the C terminus ofeach protein protrudes into the intermembrane space. Phb1p andPhb2p were not degraded in mitoplasts by proteinase K, suggestingthat the intermembrane space segments of both proteins form atightly folded domain (Fig. 4). The topology of the prohibitinsis opposite that of Yta10p and Yta12p, both of which have a largeC-terminal domain, containing the catalytic sites, exposed tothe matrix space (3, 26). Thus, two large complexes whichexpose large domains to opposite membrane surfaces exist in theinner membrane and interact with each other: the Phb1p-Phb2p complexwith an apparent molecular mass of approximately 2 MDa, and them-AAA protease with an apparent molecular mass of approximately1 MDa.

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FIG. 4. Topology of Phb1p and Phb2p in the inner membrane. Mitochondria were subfractionated by osmotic disruption of the outer membrane, and accessibility to externally added trypsin or proteinase K (PK) was examined as described in Materials and Methods. Mitochondrial fractions were analyzed by SDS-PAGE and immunostaining using antisera directed against Phb1p, Phb2p, D-lactate dehydrogenase (DLD; as a marker for the intermembrane space), and Mge1p (as a marker for the mitochondrial matrix).

Accelerated degradation of nonassembled inner membrane proteins by the m-AAA protease in the absence of prohibitins. The effect of prohibitins on the proteolytic activity of the m-AAA protease was assessed by taking advantage of the observationthat deletion of the nuclear gene COX4, encoding subunit 4 ofthe cytochrome c oxidase, results in the proteolysis of the nonassembled,mitochondrially encoded subunits Cox2p and Cox3p in the innermembrane (23). Cox2p is degraded by the i-AAA protease containingYme1p (24), whereas Cox3p is a substrate of the m-AAA protease(3, 12). After deletion of PHB1 or PHB2 in $Delta$ cox4 cells, mitochondrialtranslation products were labeled with [³⁵S]methionine. The cells were then further incubated to examinethe stability of nonassembled Cox2p and Cox3p. Cox3p was degradedwith a half-life of ~16 min in $Delta$ cox4 cells (Fig. 5A). In $Delta$ cox4cells lacking Phb1p or Phb2p, proteolysis of Cox3p was acceleratedapproximately threefold; it occurred with a half-life of ~5 min(Fig. 5A). These results suggest that prohibitins regulate theproteolytic activity of the m-AAA protease in a negative manner.The effect of prohibitins is apparently restricted to the m-AAAprotease. Degradation of nonassembled Cox2p by the i-AAA proteasewas not affected in $Delta$ cox4 cells harboring a deletion of PHB1 orPHB2 (Fig. 5A).

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FIG. 5. Accelerated degradation of nonassembled inner membrane proteins by the m-AAA protease in the absence of prohibitins. Mitochondrial translation products were labeled in the strains indicated, and cells were further incubated at 30°C to assess the stability of newly synthesized polypeptides as described in Materials and Methods. (A) Proteolysis of Cox3p and Cox2p in $Delta$ cox4 cells. Rate constants for proteolysis of Cox3p: k = 0.044 min¹ (in $Delta$ cox4 cells), k = 0.13 min¹ (in $Delta$ cox4 $Delta$ phb1 cells), and k = 0.15 min¹ (in $Delta$ cox4 $Delta$ phb2 cells). Rate constants for proteolysis of Cox2p: k = 0.036 min¹ (in $Delta$ cox4 cells), k = 0.037 min¹ (in $Delta$ cox4 $Delta$ phb1 cells), and k = 0.033 min¹ (in $Delta$ cox4 $Delta$ phb2 cells). (B) Proteolysis of Atp6p by the m-AAA protease in $Delta$ atp10 cells. Rate constants for proteolysis of Atp6p: k = 0.12 min¹ (in $Delta$ atp10 cells) and k = 0.29 min¹ (in $Delta$ atp10 $Delta$ phb1 cells).

To substantiate these conclusions, we analyzed the role of prohibitins in the degradation of the mitochondrially encoded subunit6 of the F₁F₀-ATPase (Atp6p) which is mediated by the m-AAA protease(3, 12). In the absence of the nucleus-encoded protein Atp10p(1), assembly of the F₀ moiety of the ATPase complex is defective,resulting in the proteolytic breakdown of the nonassembled F₀-subunitAtp6p. Pulse-chase experiments after labeling of mitochondrialtranslation products in $Delta$ atp10 cells revealed a half-life of ~6min for this process (Fig. 5B). Deletion of PHB1 caused a significantlyincreased rate of degradation. Proteolysis occurred with a half-lifeof ~2 min in $Delta$ atp10 $Delta$ phb1 cells (Fig. 5B). These results indicatethat prohibitins exert a general effect on the turnover of membraneproteins by the m-AAAprotease.

Impaired growth of $Delta$ phb1 and $Delta$ phb2 cells lacking m-AAA protease. The mitochondrial m-AAA protease is required for respiratory growth of S. cerevisiae but is dispensable for cell growth onfermentable carbon sources. In contrast, deletion of PHB1 or PHB2individually or deletion of both genes together does not causea detectable growth phenotype in wild-type cells (Fig. 6) (4,8). To provide genetic evidence for a functional interactionof prohibitins with the m-AAA protease, we examined the effectsof deletions in PHB1 or PHB2 in cells lacking subunits of them-AAA protease. Strikingly, the growth of $Delta$ yta10 or $Delta$ yta12 cellson fermentable carbon sources was strongly impaired in the absenceof Phb1p or Phb2p (Fig. 6). Thus, prohibitins interact also geneticallywith subunits of the m-AAA protease. On the other hand, deletionof PHB1 or PHB2 did not affect the growth of $Delta$ yme1 cells lackingi-AAA protease on fermentable or nonfermentable carbon sources(Fig. 6 and data not shown). This observation is in agreementwith our biochemical evidence and suggests a specific functionalinteraction of prohibitins with the m-AAA protease.

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FIG. 6. Impaired cell growth of $Delta$ phb1 and $Delta$ phb2 strains lacking m-AAA protease. PHB1 and PHB2 were disrupted in wild-type (WT), $Delta$ yta10, $Delta$ yta12, and $Delta$ yme1 cells by PCR-targeted homologous recombination (36). Disruptants were grown on YPD medium (rich medium containing 2% glucose) and harvested in exponential phase. Equal amounts of cells were spotted onto YPD agar plates and incubated at 30°C for 16 h. Slow growth of $Delta$ yta10 and $Delta$ yta12 cells lacking PHB1 or PHB2 was detected upon prolonged incubation of the plates (data not shown).

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Prohibitins have been implicated in diverse cellular processes ranging from cell proliferation, senescence, and the maintenanceof mitochondrial morphology. Their activity on the molecular level,however, remained obscure. Our results reveal an unexpected roleof prohibitins in the degradation of inner membrane proteins inmitochondria. A large complex containing the prohibitin homologuesPhb1p and Phb2p of S. cerevisiae associates with the m-AAA protease.The prohibitin complex appears to modulate the activity of theprotease, thus exerting a regulatory function duringproteolysis.

A physical interaction of Phb1p and Phb2p with each other and with the m-AAA protease was established by coimmunoprecipitation.Gel filtration analysis demonstrates that the m-AAA protease subunitsYta10p and Yta12p are part of a supercomplex which contains theprohibitins and has a molecular mass greater than 2 MDa. Thisobservation raises the possibility that Phb1p and Phb2p representnovel subunits of the m-AAA protease. However, while proteolysisby the m-AAA protease is required for the respiratory competenceof the cells (2, 3, 11, 35), deletion of Phb1p or Phb2pdoes not cause any detectable growth phenotype (4, 8), demonstratingthe activity of Yta10p and Yta12p in the absence of prohibitins.Consistently, the assembly of Yta10p and Yta12p is not affectedin $Delta$ phb1 cells, nor is the formation of the Phb1p-Phb2p complexaffected in cells lacking m-AAA protease. Thus, in the inner membranethere are two large protein complexes, the prohibitin complexand the m-AAA protease, which are formed independently but assemblewith eachother.

In mitochondria lacking Phb1p or Phb2p, proteolysis of nonassembled inner membrane proteins by the m-AAA protease is enhanced.Although different effects on other substrate polypeptides cannotat this point be excluded, our findings indicate a negative regulatoryrole of the prohibitins in this process. The m-AAA protease ismost likely the direct target of prohibitin action. This inferenceis suggested by the physical association of prohibitins with them-AAA protease as well as by the apparent substrate specificityof prohibitin action. The turnover of Cox3p and Atp6p, both substratesof the m-AAA protease (3, 12), was accelerated in the absenceof prohibitins, whereas the rate of Cox2p degradation by the i-AAAprotease was notaffected.

How could the prohibitin complex affect the proteolysis of membrane proteins by the m-AAA protease? The large C-terminal domainsof both Phb1p and Phb2p protrude into the intermembrane space,while Yta10p and Yta12p expose their catalytic sites to the matrix.This topology in the inner membrane suggests that the prohibitincomplex exerts its effect via the membrane-embedded N-terminalpart of the m-AAA protease which includes segments exposed tothe intermembrane space. Prohibitins may stabilize the m-AAA proteasein a conformation with lowered proteolytic activity. Alternatively,prohibitins may modulate the accessibility or conformation ofmembrane-embedded proteolytic substrates and thereby regulatethe association of substrate polypeptides with the protease. Bythis means, the prohibitins could prevent the premature degradationof nonassembled membrane proteins by the m-AAA protease and therebyensure their proper assembly. Mitochondrial preproteins, whichare present in a nonnative conformation during membrane translocation,might be protected against proteolytic attack in a similar manner.In mammalian cells, little prohibitin was found in associationwith cristae by immunoelectron microscopy, whereas it was enrichedin the periphery of mitochondria (15). Taking into account thebiochemically established localization of prohibitins to the innermembrane (4), this observation might point to an enrichmentof prohibitins near the outer membrane, i.e., in the inner boundarymembrane. A local inhibition of the m-AAA protease by prohibitinsin proximity to the import sites is thereforeconceivable.

The role of prohibitins in the degradation of mitochondrial inner membrane proteins by the m-AAA protease is reminiscent ofprevious findings in prokaryotes. The activity of the E. coliAAA protease FtsH has been demonstrated to be negatively regulatedby a complex of two homologous membrane proteins, HflK and HflC,which were found to interact directly with substrate polypeptides(16, 17). Interestingly, both HflK and HflC are distantlyrelated to prohibitin family members of various organisms (Fig.7). Like Phb1p and Phb2p, HflK and HflC are anchored to the plasmamembrane of E. coli via an N-terminal membrane-spanning segment(17). They expose a large domain to the periplasmic side ofthe plasma membrane of E. coli, i.e., opposite that of FtsH (17).The overall sequence identity of HflK and HflC to eukaryotic prohibitins,however, is significantly lower than within the prohibitin family.Nevertheless, the existence of distantly related proteins in bacteriaand eukaryotes suggests that regulatory mechanisms for AAA proteasesare conserved and derived from an early common ancestor.

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FIG. 7. Sequence similarity of E. coli HflC with prohibitin family members. Amino acid sequences of S. cerevisiae Phb1p (ScPhb1p; P40961) and prohibitin from Arabidopsis thaliana (AtPhb; U69155) and Homo sapiens (hsPhb; P35232) were aligned with E. coli HflC (EcHflC; P25661) by using the Clustal W program, version 1.7. Identical amino acid residues are shaded in black. Sequence identity between prohibitins of different organisms is over 50%. Predicted transmembrane segments at the N termini are underlined. E. coli HflC show 20% identical and 33% homologous residues with S. cerevisiae Phb1p and 13% identical and 29% homologous residues with S. cerevisiae Phb2p. We observed a similar degree of similarity between E. coli HflK and S. cerevisiae Phb1p and Phb2p (data not shown).

The functional interaction of prohibitins with the m-AAA protease raises the intriguing question of whether cellular activitiespreviously attributed to prohibitins reflect their regulatoryroles in membrane protein degradation. The observed requirementof prohibitins for efficient cell growth in the absence of them-AAA protease provides genetic evidence for a functional relationshipof both complexes but cannot be explained by a physical interaction.Therefore, additional functions of prohibitins in mitochondria,likely linked to the degradation of inner membrane proteins andthe activity of the m-AAA protease, must exist. Prohibitins haverecently been implicated in the regulation of mitochondrial morphology,as they were found to genetically interact with the mitochondrialinheritance components Mdm10p, Mdm12p, and Mmm1p in the outermembrane (4). In view of our results, it is conceivable thatthis genetic interaction is caused by alterations in the turnoverof inner membrane proteins in the absence of prohibitins. In contrastto cells lacking the i-AAA protease subunit Yme1p (6), however,evidence for defects in mitochondrial morphology in the absenceof the m-AAA protease, or after its overexpression, is lacking.Alternatively, the genetic interaction of prohibitins with mitochondrialinheritance components may reflect nonproteolytic functions ofprohibitins. In view of the size of the prohibitin complex inthe inner membrane, one can envision a scaffolding function ofprohibitins which may allow for the assembly of a variety of mitochondrialproteins. Further insights into this question will require theidentification of additional subunits of the prohibitincomplex.

In view of the sequence conservation of prohibitins and AAA proteases from yeast to human (sequence identity of >50%), similarfunctions in all eukaryotic cells are likely. Another intriguingquestion raised by our findings is, therefore, how the effectsof prohibitins on the m-AAA protease are linked to their rolesin proliferation of mammalian cells and for cellular senescence.Alterations in mitochondrial physiology may change the energylevel in the cell or its redox balance and thereby affect cellproliferation and aging. Prohibitins may affect mitochondrialactivity by modulating the turnover of a short-lived regulatoryprotein by the m-AAA protease. It is therefore of interest toidentify such putative substrates of the m-AAA protease and furthercharacterize the specificity of prohibitin action duringproteolysis.

	ACKNOWLEDGMENTS

We thank B. Guiard for the COX4 disruption construct, S. Ackermann for the $Delta$ atp10 strain, A. Tzagoloff for critically readingthe manuscript, and P. Coates for yeast strains and stimulatingdiscussions during early phases of the project. The technicalassistance of Petra Robisch and Alexandra Stiegler is gratefullyacknowledged.

This work was supported by grants from the Deutsche Forschungsgemeinschaft (La918/1-2; SFB 184/B21) and the Medizinische Wochenschriftto T.L.

	FOOTNOTES

^* Corresponding author. Mailing address: Institut für Physiologische Chemie, Goethestr. 33, 80336 Munich, Germany. Phone: 4989 5996 283. Fax: 49 89 5996 270. E-mail: Langer{at}bio.med.uni-muenchen.de.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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1.	Ackermann, S. H., and A. Tzagoloff. 1990. ATP10, a yeast nuclear gene required for the assembly of the mitochondrial F₁-F₀ complex. J. Biol. Chem. 265:9952-9959[Abstract/Free Full Text].
2.	Arlt, H., G. Steglich, R. Perryman, B. Guiard, W. Neupert, and T. Langer. 1998. The formation of respiratory chain complexes in mitochondria is under the proteolytic control of the m-AAA-protease. EMBO J. 17:4837-4847[Medline].
3.	Arlt, H., R. Tauer, H. Feldmann, W. Neupert, and T. Langer. 1996. The YTA10-12-complex, an AAA protease with chaperone-like activity in the inner membrane of mitochondria. Cell 85:875-885[Medline].
4.	Berger, K. H., and M. P. Yaffe. 1998. Prohibitin family members interact genetically with mitochondrial inheritance components in Saccharomyces cerevisiae. Mol. Cell. Biol. 18:4043-4052[Abstract/Free Full Text].
5.	Brodsky, J. L., and A. A. McCracken. 1997. ER-associated and proteasome-mediated protein degradation: how two topologically restricted events came together. Trends Cell Biol. 7:151-156.
6.	Campbell, C. L., N. Tanaka, K. H. White, and P. E. Thorsness. 1994. Mitochondrial morphological and functional defects in yeast caused by yme1 are suppressed by mutation of a 26S protease subunit homologue. Mol. Biol. Cell 5:899-905[Abstract].
7.	Casari, G., M. De-Fusco, S. Ciarmatori, M. Zeviani, M. Mora, P. Fernandez, G. DeMichele, A. Filla, S. Cocozza, R. Marconi, A. Durr, B. Fontaine, and A. Ballabio. 1998. Spastic paraplegia and OXPHOS impairment caused by mutations in paraplegin, a nuclear-encoded mitochondrial metalloprotease. Cell 93:973-983[Medline].
8.	Coates, P. J., D. J. Jamieson, K. Smart, A. R. Prescott, and P. A. Hall. 1997. The prohibitin family of mitochondrial proteins regulate replicative lifespan. Curr. Biol. 7:R607-R610.
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