Biogenesis of Tim Proteins of the Mitochondrial Carrier Import Pathway: Differential Targeting Mechanisms and Crossing Over with the Main Import Pathway

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Vol. 10, Issue 7, 2461-2474, July 1999

Biogenesis of Tim Proteins of the Mitochondrial Carrier Import Pathway: Differential Targeting Mechanisms and Crossing Over with the Main Import Pathway

Martin Kurz,^* Heiko Martin,^* Joachim Rassow,^* Nikolaus Pfanner,^* and Michael T. Ryan^*

^*Institut für Biochemie und Molekularbiologie and Institut für Biologie, Universität Freiburg, D-79104 Freiburg, Germany

Submitted November 18, 1998; Accepted May 4, 1999
Monitoring Editor: Elizabeth Anne Craig

	ABSTRACT

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERNCES

Two major routes of preprotein targeting into mitochondria are known. Preproteins carrying amino-terminal signals mainly useTom20, the general import pore (GIP) complex and the Tim23-Tim17complex. Preproteins with internal signals such as inner membranecarriers use Tom70, the GIP complex, and the special Tim pathway,involving small Tims of the intermembrane space and Tim22-Tim54of the inner membrane. Little is known about the biogenesis andassembly of the Tim proteins of this carrier pathway. We reportthat import of the preprotein of Tim22 requires Tom20, althoughit uses the carrier Tim route. In contrast, the preprotein ofTim54 mainly uses Tom70, yet it follows the Tim23-Tim17 pathway.The positively charged amino-terminal region of Tim54 is requiredfor membrane translocation but not for targeting to Tom70. Inaddition, we identify two novel homologues of the small Tim proteinsand show that targeting of the small Tims follows a third newroute where surface receptors are dispensable, yet Tom5 of theGIP complex is crucial. We conclude that the biogenesis of Timproteins of the carrier pathway cannot be described by eitherone of the two major import routes, but involves new types ofimport pathways composed of various features of the hitherto knownroutes, including crossing over at the level of theGIP.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERNCES

Many mitochondrial precursor proteins are synthesized with amino-terminal targeting sequences, termed presequences, that directthe proteins to the organelle and across the outer and inner membranes(Ryan and Jensen, 1995; Schatz and Dobberstein, 1996; Neupert,1997; Pfanner et al., 1997; Ryan and Pfanner, 1998). In the matrix,the presequences are typically cleaved off by the mitochondrialprocessing peptidase. A number of mitochondrial preproteins arenot synthesized with cleavable targeting signals. A few preproteinswere shown to contain the targeting information at the amino-terminalportion of the protein that is to carry a "noncleaved presequence"(Hurt et al., 1985; Arakawa et al., 1990; Rospert et al., 1993;Hahne et al., 1994; Jarvis et al., 1995); however, most noncleavablepreproteins, notably those that are membrane proteins, seem tocontain internal targeting information distributed over variousregions of the preprotein (Pfanner et al., 1987a; Smagula andDouglas, 1988; Davis et al., 1998; Káldi et al., 1998). Typicalrepresentatives are the members of the large family of inner membranemetabolite carriers, such as the ADP/ATP carrier(AAC).

The mitochondrial machinery for the import of presequence-containing preproteins has been studied in detail. The presequencesare typically recognized by the surface receptor Tom20, the 20-kDasubunit of the translocase of the outer membrane (Söllner etal., 1989; Ramage et al., 1993; Brix et al., 1997). Subsequently,the preproteins are transferred to the general import pore (GIP)complex where they interact with Tom22 and Tom5 and are translocatedthrough the import channel formed by Tom40 (Vestweber et al.,1989; Kiebler et al., 1993; Dietmeier et al., 1997; Hill et al.,1998). The presequences bind to Tim23 of the translocase of theinner membrane and in a membrane potential ( $Delta$ $psi$ )-dependent reactionmove through the inner membrane channel, that is, the Tim corecomplex formed by Tim23 and Tim17 (Dekker et al., 1993, 1997;Emtage and Jensen, 1993; Ryan et al., 1994; Bauer et al., 1996).Matrix-located heat shock protein 70 (mtHsp70) cooperates withTim44 to drive the completion of preprotein translocation (Kronidouet al., 1994; Rassow et al., 1994; Schneider et al., 1994; Vooset al., 1996; Bömer et al., 1998).

The inner membrane carriers follow a different import route that converges with the presequence pathway only at the levelof the GIP complex. The carrier preproteins such as AAC are preferentiallyrecognized by Tom70 before their transfer to the GIP (Hines etal., 1990; Söllner et al., 1990). At the trans side of the outermembrane, the presequence and carrier pathways diverge (Moczkoet al., 1997; Kübrich et al., 1998). Recent studies led to theidentification of a number of new Tim proteins that mediate thetranslocation through the intermembrane space and insertion intothe inner membrane. Three homologous small Tim proteins of theintermembrane space, Tim9, Tim10, and Tim12, bind the carrierpreproteins (Koehler et al., 1998a,b; Sirrenberg et al., 1998)and transfer them to a translocase of the inner membrane thatcontains Tim22 and Tim54 (Sirrenberg et al., 1996; Kerscher etal., 1997). The carrier proteins contain six membrane-spanningsegments each and are inserted into the inner membrane in a $Delta$ $psi$ -dependentmanner via Tim22-Tim54. Tim23, Tim17, and Tim22 contain a homologousmembrane domain with four predicted membrane-spanning segments,and recent evidence indicates that Tim23 and most likely Tim17and Tim22 are also imported via the carrier Tim pathway (Kerscheret al., 1997; Káldi et al., 1998).

Little is known about the actual biogenesis of the Tim proteins that are involved in the import of carrier preproteins. Forthis study, we have analyzed targeting and translocation of theprecursors of these Tim proteins. We report that the targetingpathways of Tim22 and Tim54 reveal a new principle of combinationof different portions of the main (presequence) pathway and thespecial (carrier) pathway. The crossing over occurs at the levelof the GIP complex. Moreover, import of the small Tims providesthe first example for a preferential targeting via Tom5 and notvia the trypsin-accessible domains of the largerreceptors.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERNCES

Construction of Plasmids for in Vitro Transcription

The open reading frames of yeast TIM54 (Kerscher et al., 1997), TIM22 (Sirrenberg et al., 1996), TIM13 (Accession No. P53299),TIM12 (Jarosch et al., 1996), TIM10 (Jarosch et al., 1997), TIM9(Koehler et al., 1998b), and TIM8 (Accession No. Y13136) wereamplified by PCR and individually cloned into pGEM-4Z (Promega,Madison, WI). Tim54 $Delta$ N was obtained by PCR using a downstream vectorprimer and a primer containing the SP6 polymerase binding siteand an 18-nucleotide stretch encoding residues 39-44 of Tim54(5'-GGA TTA GGT GAC ACT ATA GAA ATG ATC TTT TGG TCT GTG-3').

Import of Preproteins Into Isolated Mitochondria

The yeast strains used in this study are shown in Table 1. Mitochondria were isolated from yeast cells grown in YPG media(1% yeast extract, 2% bacto-peptone, and 3% glycerol) accordingto Daum et al. (1982) and Hartl et al. (1987). Radiolabeled preproteinswere obtained by in vitro transcription and translation reactionsusing rabbit reticulocyte lysate (Amersham, Arlington Heights,IL) in the presence of [³⁵S]methionine/cysteine (Söllner et al., 1991).

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Table 1. Saccharomyces cerevisiae strains used in this study

Mitochondrial in vitro import reactions were performed in BSA-containing buffer (3% [wt/vol] fatty acid-free BSA, 80 mM KCl,5 mM MgCl₂, 10 mM MOPS/KOH, pH 7.2) in the presence of 2 mM ATPand 2 mM NADH. To dissipate the membrane potential, 8 µM antimycinA, 20 µM oligomycin, and 1 µM valinomycin (Sigma, St. Louis, MO)were added to the import reaction. Reticulocyte lysate containingradiolabeled preproteins (2.5-10% [vol/vol] of import reaction)was incubated with mitochondria (25-50 µg protein) at 25°C forvarying times. Valinomycin (1 µM) was added to stop import, andsamples were subsequently treated with or without proteinase K(50 µg/ml) on ice for 15 min. The protease was inactivated bythe addition of 1 mM PMSF, and samples were incubated for a further10 min at 4°C.

For trypsin treatment of accessible Tom receptor domains, mitochondrial samples in SEM buffer (250 mM sucrose, 1 mM EDTA,10 mM MOPS/KOH, pH 7.2) were incubated with trypsin (20 µg/ml)for 20 min on ice. Trypsin was inactivated on the addition ofa 30-fold excess of soybean trypsin inhibitor (Type II-S, Sigma)and samples were incubated for an additional 10 min on ice beforefurther manipulations. For control samples, a 30-fold excess ofsoybean trypsin inhibitor was added to mitochondria before trypsinaddition. Preproteins were imported for 15 min at 25°C beforeproteinase Kdigestion.

For import of preproteins into ssc1-3 mitochondria (Gambill et al., 1993), a 15 min incubation at 37°C was performed withboth wild-type and ssc1-3 mitochondria before import studies wereperformed at 25°C.

Swelling of mitochondrial samples was prepared by resuspending the mitochondrial pellets in EM buffer (1 mM EDTA, 10 mM MOPS/KOH,pH 7.2) and incubating the samples on ice for 15 min. ATP wasdepleted from mitochondrial samples and reticulocyte lysates accordingto Glick (1995). Preproteins were imported for 15 min at 25°Cbefore proteinase Kdigestion.

After treatments, mitochondrial pellets were lysed in the appropriate detergent-containing buffer and applied to SDS or bluenative polyacrylamidegels.

Accumulation of b₂(167) $Delta$ -dihydrofolate Reductase Across Mitochondrial Membranes

Mitochondria (50 µg) were incubated with 1 µg purified b₂(167) $Delta$ -dihydrofolate reductase (DHFR) (Dekker et al., 1997) for 15min at 25°C in the presence of 2 µM methotrexate. After accumulation,mitochondria were reisolated, washed with SEM buffer containing2 µM methotrexate, and finally resuspended in BSA-containing buffercontaining 2 µM methotrexate before use in further importassays.

Blue Native Gel Electrophoresis

Blue native PAGE was performed essentially as described previously (Schägger and von Jagow, 1991; Schägger et al., 1994;Dekker et al., 1997). Briefly, mitochondrial pellets (25-100 µgprotein) were lysed in 50 µl ice-cold digitonin buffer (1% [wt/vol]digitonin, 20 mM Tris-HCl, pH 7.4, 0.1 mM EDTA, 50 mM NaCl, 10%[vol/vol] glycerol, 1 mM PMSF) (Blom et al., 1995). After a clarifyingspin, 5 µl of sample buffer (5% [wt/vol] Coomassie brilliant blueG-250, 100 mM Bis-Tris, pH 7.0, 500 mM 6-aminocaproic acid) wereadded, and the samples were electrophoresed at 4°C through a 6-16%polyacrylamide gradientgel.

For immunoblotting, the native gel was soaked in blot buffer (20 mM Tris-base, 150 mM glycine, 20% [vol/vol] methanol, 0.08%[wt/vol] SDS) before transfer onto PVDF membranes (Millipore,Bedford, MA) using the semidry blotting technique (Harlow andLane, 1988). Immunodecoration was performed according to standardprocedures (Harlow and Lane, 1988), and detection was achievedusing the ECL method (Amersham). For detection of radiolabeledproteins, the dried gel or PVDF membrane was exposed to phosphorimagestorage cassettes before phosphorimage analysis (Molecular Dynamics,Sunnyvale,CA).

Miscellaneous

Sequence alignments were generated with MegAlign (DNA Star Inc., Madison, WI) using the Clustal method and the PAM250 weighttable.

SDS-PAGE of larger proteins (e.g., Tim54 and Tim22) was performed according to Laemmli (1970), and urea SDS-PAGE (Ito et al.,1980) was used for the analysis of the small Timproteins.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERNCES

The Preproteins of Tim22 and Tim54 Require Different Surface Receptors for Import

The preproteins of Tim22 and Tim54 were synthesized in vitro in rabbit reticulocyte lysate in the presence of [³⁵S]methionine/cysteine and incubated with isolated yeast wild-typemitochondria. In the presence of a membrane potential across theinner membrane, the preproteins were transported to a protease-protectedlocation (Figure 1A, lanes 1-3 and 5-7). On dissipation of the $Delta$ $psi$ , import was blocked (Figure 1A, lanes 4 and 8).

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Figure 1. Biogenesis of Tim22 and Tim54. (A) Import kinetics of Tim22 and Tim54. ³⁵S-labeled Tim22 and Tim54 preproteins were imported into mitochondria for different times in the presence (lanes 1-3, 5-7) or absence (lanes 4 and 8) of a membrane potential ( $Delta$ $psi$ ) as described in MATERIALS AND METHODS. After import, mitochondria were treated with 50 µg/ml proteinase K and subjected to SDS-PAGE. (B) Assembly of Tim22 and Tim54 into the carrier translocase. Mitochondria were solubilized in digitonin-containing buffer and subjected to blue native gel electrophoresis. The gel was blotted, and lanes were immunodecorated with antibodies specific for Tom40 (lane 1), Tim23 (lane 2), or Tim22 (lane 3). For lanes 4-11, Tim22 and Tim54 preproteins were imported into mitochondria as in A, and mitochondria were electrophoresed on blue native PAGE as above. (C) The import of Tim54 and Tim22 requires surface receptors. Mitochondria were pretreated with 20 µg/ml trypsin for 20 min, before inactivation with a 30-fold excess of trypsin inhibitor (lane 2). For control samples (lane 1), trypsin-inhibitor was added to mitochondria before the addition of trypsin. ³⁵S-labeled Tim22 and Tim54 preproteins were subjected to mitochondrial import as well as ³⁵S-labeled porin, AAC, and Su9-DHFR preproteins, which served as controls. Samples were treated with proteinase K before SDS-PAGE analysis. (D) The import of Tim22 and Tim54 show differential requirements for ATP. ³⁵S-labeled Tim22, Tim54, AAC, and Su9-DHFR in reticulocyte lysates were depleted of ATP. Preproteins were imported into mitochondria in the presence (lane 1) or absence of added ATP. In lane 2, mitochondria were additionally blocked in the export of ATP from the matrix according to Glick (1995)

. Samples were treated with proteinase K before SDS-PAGE analysis. Radiolabeled proteins were detected by storage phosphorimage cassette technology.

To determine whether the proteins were correctly imported and assembled, we used blue native electrophoresis of digitonin-lysedmitochondria, which allows a separation of the mitochondrial translocasecomplexes (Dekker et al., 1996-1998): the large Tom complex, termedthe GIP complex (Figure 1B, lane 1); the Tim core complex containingTim23 and Tim17 (Figure 1B, lane 2); and a ~300-kDa complex containingTim22, termed the carrier translocase (Figure 1B, lane 3). Wefound that both imported Tim22 and Tim54 were efficiently assembledinto the 300-kDa translocase complex in a $Delta$ $psi$ -dependent manner(Figure 1B, lanes 4-6 and 8-10).

By a pretreatment of the mitochondria with trypsin, the cytosolic domains of the import receptors Tom20, Tom22, and Tom70are removed (Alconada et al., 1995; Dietmeier et al., 1997). Theimport of both Tim22 and Tim54 into trypsin-treated mitochondriawas inhibited, indicating a dependence on one or more of thesesurface receptors (Figure 1C, lane 2). Such pretreatment alsoinhibited the import of the outer membrane protein porin and amatrix-targeted fusion protein between the presequence of F_o-ATPasesubunit 9 and the entire dihydrofolate reductase (Su9-DHFR), whichmainly uses Tom20 (Hines et al., 1990; Moczko et al., 1994; Pfanneret al., 1997). The import of AAC, which mainly uses Tom70 as itsreceptor (Hines et al., 1990; Söllner et al., 1990), was alsoinhibited (Figure 1C). It has been shown previously that thereis a differential dependence on cytosolic ATP and cofactors forthe targeting of preproteins to either Tom20 or Tom70 (Hachiyaet al., 1995; Komiya et al., 1996, 1997). We asked how the depletionof cytosolic ATP affected the import of Tim22 and Tim54 and founda strong difference between both preproteins. Although the importof Tim54 was inhibited by the ATP depletion, the import of Tim22was unchanged (Figure 1D, lane 2). As a control, we show thatdepletion of cytosolic ATP also inhibited the import of the preproteinAAC but not Su9-DHFR (Figure 1D) (Wachter et al., 1994).

We thus examined the possibility that Tim22 and Tim54 interacted with different receptors by using mitochondria isolated fromyeast strains lacking TOM20 or TOM70 genes, respectively. Becausea lack of Tom20 causes a reduction in the mitochondrial levelsof Tom22 and thus indirectly a reduction of the mitochondrialmembrane potential (Lithgow et al., 1994; Gärtner et al., 1995b;Hönlinger et al., 1995b), we used a tom20 $Delta$ strain where TOM22was put on a high-copy number plasmid to restore the mitochondriallevels of Tom22 and the membrane potential (Hönlinger et al.,1995b). Import of the preprotein of Tim22 was strongly inhibitedin tom20 $Delta$ mitochondria but practically unchanged in tom70 $Delta$ mitochondriain comparison to wild-type mitochondria (Figure 2, left panel).In contrast, the import of Tim54 was strongly inhibited in tom70 $Delta$ mitochondria, but only mildly affected in tom20 $Delta$ mitochondria(Figure 2, middle panel). Furthermore, the presequence-containingpreprotein Su9-DHFR displayed import characteristics similar tothose of Tim22 in its receptor requirements (Figure 2, right panel).In the absence of a membrane potential across the inner membrane,import of the preproteins was inhibited in all cases (Figure 2,lanes 5, 10, and 15), confirming the specificity of the importprocesses into the mutant mitochondria.

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Figure 2. Tim22 and Tim54 require different outer membrane receptors for their import into mitochondria. In vitro synthesized ³⁵S-labeled Tim22 (left panel), Tim54 (middle panel), and Su9-DHFR (right panel) were imported into mitochondria isolated from wild-type (WT), tom70 $Delta$ , tom20 $Delta$ , or tom5 $Delta$ yeast cells for the indicated times in the presence (lanes 1-4, 6-9, and 11-14) or absence (lanes 5, 10, and 15) of a membrane potential ( $Delta$ $psi$ ). Samples were treated with proteinase K before SDS-PAGE analysis. Radiolabeled proteins were detected by storage phosphorimage cassette technology and quantitated using ImageQuant software (Molecular Dynamics). The import observed in wild-type mitochondria after 20 min was set at 100% (control).

In addition, we used mitochondria from a yeast strain lacking the small subunit Tom5 of the GIP complex. Tom5 is resistantto a treatment with trypsin and functions after the surface receptorsat the entry site of the import pore where the presequence andcarrier routes converge (Dietmeier et al., 1997). The import ofboth Tim22 and Tim54 along with Su9-DHFR were inhibited in tom5 $Delta$ mitochondria (Figure 2, bottom panels). We conclude that the preproteinof Tim54 is directed into mitochondria preferentially by Tom70in an ATP-dependent reaction, whereas the preprotein of Tim22,like the presequence-containing preprotein Su9-DHFR, uses Tom20as receptor in a manner independent of cytosolic ATP. Both importpathways join at the entry site of the GIP that includesTom5.

Different Tim Pathways for the Preproteins of Tim22 and Tim54

Koehler et al. (1998a) and Sirrenberg et al. (1998) showed that mutations in Tim components of the carrier pathway, includingTim10, caused a strong reduction in the mitochondrial level ofTim22, suggesting that the preprotein of Tim22 itself was importedvia the carrier Tim pathway, as shown previously for the homologousproteins Tim23 and Tim17 (Dekker et al., 1997; Kerscher et al.,1997; Káldi et al., 1998). We used two assays to determine whichTim pathway was used by the preprotein of Tim54 in comparisonwith the import ofTim22.

Accumulation of Chemical Amounts of a Presequence-Containing Preprotein in Translocation Contact Sites A matrix-targeted preprotein, consisting of a portion of precytochrome b₂ and the entire dihydrofolate reductase [b₂(167) $Delta$ -DHFR],can be prepared as a soluble species in large amounts. After stabilizationof the DHFR moiety with methotrexate, the preprotein can be accumulatedin the mitochondrial import sites, spanning both the Tom machineryand the Tim23-Tim17 machinery (Dekker et al., 1997). Thereby thesubsequent import of preproteins using the Tim23-Tim17 pathwayis impaired in mitochondria with accumulated b₂(167) $Delta$ -DHFR. Theimport of carrier proteins is only slightly affected because theTom complexes are approximately four times more abundant thanthe Tim23-Tim17 complexes, and thus most Tom complexes are notoccupied by the b₂(167) $Delta$ -DHFR preprotein (Dekker et al., 1997).We accumulated methotrexate-bound b₂(167) $Delta$ -DHFR in mitochondriaand tested the import kinetics of different preproteins. Althoughthe import of Tim22 was only slightly inhibited (Figure 3A), asignificant reduction in import was observed for the preproteinof Tim54 (Figure 3B). For comparison, the import of AAC was onlyslightly affected (Figure 3C), but the import of the Rieske Fe/Sprotein, a typical presequence-containing preprotein, was inhibited(Figure 3D). Furthermore, the analysis of inner-membrane insertionand assembly of the imported preproteins by blue native electrophoresisrevealed that Tim54 assembly was reduced in mitochondria containingaccumulated preprotein (Figure 3E).

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Figure 3. The preproteins of Tim22 and Tim54 use different Tim pathways for their import. Mitochondria were incubated in the presence or absence of b₂(167) $Delta$ -DHFR and methotrexate for 15 min at 25°C. Mitochondria were reisolated, washed, and resuspended in import buffer containing methotrexate before the addition of ³⁵S-labeled (A) Tim22, (B) Tim54, (C) the ADP/ATP carrier (AAC), or (D) the Fe/S protein (Fe/Sp). Import proceeded for the indicated times, and mitochondria were subsequently treated with 50 µg/ml proteinase K. Where indicated, the membrane potential ( $Delta$ $psi$ ) was dissipated before the addition of preprotein. Mitochondrial proteins were separated by SDS-PAGE and radiolabeled proteins were detected by storage phosphorimage cassette technology. Processing of the presequence of the Fe/S protein by matrix-located proteases generates intermediate (i) and mature (m) forms as indicated. The amount of imported preprotein was quantitated using ImageQuant software. The import in the absence of b₂(167) $Delta$ -DHFR after the longest import time was set to 100% for each preprotein. (E) Tim22, Tim54, and AAC preproteins were imported into mitochondria for 30 min in the presence or absence of accumulated b₂(167) $Delta$ -DHFR and subjected to blue native PAGE. Assembled preprotein was quantitated using ImageQuant software where 100% was set to preprotein assembled in the absence of b₂(167) $Delta$ -DHFR.

A Point Mutation in TIM23 Mitochondria from the yeast mutant tim23-2 carry an amino acid substitution in Tim23 that causes a labilization of the Tim23-Tim17complex and thus a reduction in preproteins imported via Tim23-Tim17(Bömer et al., 1997a; Dekker et al., 1997). The import of Tim22into tim23-2 mitochondria occurred with wild-type rates, likethe import of the ADP/ATP carrier (Figure 4A, first and thirdpanels). The import of Tim54 into tim23-2 mitochondria was partlyreduced, comparable to the import of the Fe/S protein (Figure4A, compare second and fourth panels, lanes 5-7 with lanes 1-3;Figure 4B, compare columns 2 and 4 [showing the degree of inhibition]).

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Figure 4. Dependence of Tim54 import on Tim23 and matrix Hsp70. (A) The import of the Fe/S protein and Tim54 is impaired in tim23-2 mitochondria. ³⁵S-labeled preproteins of Tim22, Tim54, the ADP/ATP carrier (AAC), or the Fe/S protein (Fe/Sp) were imported into mitochondria isolated from wild-type (WT) cells or tim23-2 cells in the presence (lanes 1-3, 5-7) or absence (lanes 4 and 8) of a membrane potential ( $Delta$ $psi$ ) for the indicated times. After import, samples were treated with 50 µg/ml proteinase K and subjected to SDS-PAGE. (B) The inhibition of preprotein import in tim23-2 mitochondria observed after 15 min import was quantified in comparison to the import yield into wild-type mitochondria (control). (C) Inactivation of matrix Hsp70 has a partial effect on the import of Tim54 but no effect on Tim22. ³⁵S-labeled preproteins corresponding to Tim22, Tim54, the $beta$ -subunit of the F₁-ATPase (F₁ $beta$ ), or the Fe/S protein (Fe/Sp) were imported into wild-type mitochondria and mitochondria containing a temperature-sensitive mutation in SSC1, encoding the matrix-located Hsp70 (ssc1-3). Processing of F₁ $beta$ generates the mature (m) product as shown. After import, samples were treated with 50 µg/ml proteinase K and subjected to SDS-PAGE. The amount of protein imported into wild-type mitochondria after 15 min was set to 100% (control).

These results demonstrate the independence of the import of Tim22 from the Tim23-Tim17 pathway, yet a dependence of the importof Tim54 on this pathway. Most preproteins using the Tim23-Tim17pathway are transported into the matrix and thereby depend strictlyon the mtHsp70 system (Gambill et al., 1993

; Glick et al., 1993

;Voos et al., 1993

, 1996

; Stuart et al., 1994

). Some preproteinswith hydrophobic sorting signals/membrane anchors branch fromthis pathway at the level of Tim23 (Bömer et al., 1997a

). Thesepreproteins apparently leave the Tim23-Tim17 machinery laterallyinto the membrane without a strict need for mtHsp70 and are thusnot at all, or only partially, inhibited by an inactivation ofmtHsp70 (Glick et al., 1993

; Voos et al., 1993

; Gärtner et al.,1995a

; Gruhler et al., 1995

). To test whether Tim54 belongedto this special class of preproteins, we used ssc1-3 mitochondriathat have an inactivated mtHsp70 (Gambill et al., 1993

; Voos etal., 1993

). Indeed, the import of Tim54 was only partially impairedby the inactivation of mtHsp70 (Figure 4C, top right panel), whereasthe import of the matrix-targeted preproteins F₁-ATPase subunit $beta$ and Fe/S protein was severely inhibited (Figure 4C, bottom panels).The import of Tim22, which is imported via the carrier Tim route,was not affected by the ssc1-3 mutation (Figure 4C, top left panel),as observed with the precursors of Tim17 and Tim23 (Bömer etal., 1997b

). These results suggest that Tim54 uses the Tim23-Tim17pathway for its import, but leaves the matrix route before theFe/S protein, at about the level where the action of mtHsp70 isneeded.

Most preproteins using Tim23-Tim17 that we studied so far contain an amino-terminal targeting signal that is a positivelycharged presequence. Although Tim54 is not proteolytically processedduring import (Kerscher et al., 1997

), an inspection of the primarystructure revealed that the amino-terminal region of Tim54 containsan abundance of positively charged residues (Figure 5A). We deletedthe first 38 residues of Tim54, leading to the construct Tim54 $Delta$ N,which is synthesized from the methionine at residue 39 (Figure5A). The import of Tim54 $Delta$ N into a protease-protected locationof mitochondria was completely blocked (Figure 5B, bottom panel,lanes 5-7). The binding of the mutant preprotein to mitochondria,however, was still possible (Figure 5B, top panel, lanes 5-8).The binding of preproteins to isolated mitochondria typicallyincludes two fractions: a specific binding to receptors and anonspecific binding to the organelle surface (Pfanner et al.,1987b

; Söllner et al., 1991

; Alconada et al., 1995

). To testwhether Tim54 $Delta$ N bound to mitochondria included specific bindingto receptors, we compared its association with both wild-typemitochondria and mitochondria lacking Tom20 or Tom70. The bindingof Tim54 $Delta$ N to mitochondria was reduced by ~60% tom70 $Delta$ mitochondria(Figure 5C, column 6), comparable to the binding of full-lengthTim54 (Figure 5C, column 3), whereas for tom20 $Delta$ mitochondria,an increase in the binding of Tim54 $Delta$ N was observed (Figure 5C,column 2 vs. 5). We conclude that a significant fraction of Tim54 $Delta$ Nbound to mitochondria specifically interacts via Tom70, indicatingthat the positively charged amino-terminal segment is dispensablefor this receptor interaction. The amino-terminal segment, however,is required for translocation of Tim54 into mitochondria, suggestingthat both the amino-terminal portion of Tim54 and a more C-terminalregion are involved in the import of this preprotein.

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Figure 5. Different portions of Tim54 are needed for receptor interaction and membrane translocation. (A) Generation of a construct lacking the first 38 amino acids of Tim54 (Tim54 $Delta$ N) removes a number of basic residues. Positively and negatively charged residues are indicated. Tim54 $Delta$ N initiates from the internal methionine shown at position 39. (B) Tim54 $Delta$ N is not imported into mitochondria. ³⁵S-labeled preproteins corresponding to Tim54 (lanes 1-4) and Tim54 $Delta$ N (lanes 5-8) were incubated with mitochondria for the indicated times in the presence (lanes 1-3, 5-7) or absence (lanes 4 and 8) of a membrane potential ( $Delta$ $psi$ ). After import, samples were halved and treated with (bottom panel) or without (top panel) proteinase K (Prot. K). (C) Binding of Tim54 $Delta$ N to mitochondria is inhibited by a lack of Tom70. ³⁵S-labeled Tim54 and Tim54 $Delta$ N preproteins were arrested on the outer membrane by depleting ATP from mitochondria and reticulocyte lysates. Samples were analyzed by SDS-PAGE, and radiolabeled proteins were quantified using ImageQuant software. Binding to isolated mitochondria from wild-type cells (WT; control) was compared with binding to mitochondria lacking Tom20 (tom20 $Delta$ ) or Tom70 (tom70 $Delta$ ).

A Role for Tom5 in Targeting of the Small Tims to Mitochondria

Tim9, Tim10, and Tim12 are the three currently known small Tim proteins that are homologous to each other. A search in theyeast genome revealed the presence of two additional small Timproteins, termed Tim8 and Tim13, with significant homology tothe other three Tims, including a complete conservation of fourcysteine residues (Figure 6A). The preproteins of the small Timswere synthesized in reticulocyte lysates and labeled with [³⁵S]methionine/cysteine. Like the known small Tims, Tim8 and Tim13were transported to a protease-protected location in mitochondria(Figure 6B, lane 1). After swelling of the mitochondria that ledto an opening of the intermembrane space with an efficiency of~80-90% (Bömer et al., 1997a,b), each small Tim became accessibleto protease (Figure 6B, lane 2), demonstrating that Tim8 and Tim13also were located in the intermembrane space. As control, immunodecorationshowed that endogenous Tim10 along with the intermembrane spaceprotein cytochrome b₂ were accessible to protease after swellingbut not the matrix-located protein Mge1 (Figure 6B, Immunodecoration).

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Figure 6. A family of small Tim proteins with a preference for import via Tom5. (A) Identification of two new small Tim homologues. Sequence alignment of the five small Tim proteins. Amino acid identities are shown in white lettering against black; conserved residues are shown in black lettering against gray. The putative Zn-finger motif cysteines are indicated by an asterisk above. (B) The small Tim proteins are imported into the intermembrane space. ³⁵S-labeled Tim13, Tim12, Tim10, Tim9, and Tim8 preproteins were imported into mitochondria for 10 min at 25°C. After import, mitochondria were isolated and treated with proteinase K (lane 1) or first swollen before proteinase K treatment (lane 2). As controls for swelling and proteinase K treatment, mitochondria were immunodecorated with antibodies against the intermembrane space proteins Tim10 and cytochrome b₂ (Cyt b₂) and the matrix protein Mge1. (C) Mitochondrial import of the small Tim proteins can occur in the absence of trypsin-accessible receptor domains. Before import of ³⁵S-labeled Tim9, Tim10, and Tim13, mitochondria were pretreated with active (lanes 2, 4, 6) or inactive trypsin (lanes 1, 3, 5; control). All import reactions were treated with proteinase K before SDS-PAGE and quantification. (D) The import of the small Tim proteins preferentially depends on Tom5. ³⁵S-labeled Tim9 and Tim13 were imported into wild-type (WT) mitochondria or mitochondria lacking Tom70 (tom70 $Delta$ ), Tom20 (tom20 $Delta$ ), or Tom5 (tom5 $Delta$ ) for the indicated time points. Samples were treated with proteinase K and analyzed by SDS-PAGE and digital autoradiography.

We then investigated the targeting principles of the small Tims. No obvious mitochondrial targeting signals are observed inany of the small Tim sequences (Figure 6A), and our unpublishedresults along with those of Koehler et al. (1998b) showed thatthe small Tim proteins do not require a membrane potential fortheir insertion into the intermembrane space. Surprisingly, apretreatment of the mitochondria with trypsin did not inhibitthe import of the small Tims, as shown here with the preproteinsof Tim9, Tim10, and Tim13 (Figure 6C, columns 2, 4, and 6), indicatingthat they did not strictly require mitochondrial surface receptors.Indeed, import of the small Tims was not affected by a deletionof TOM70 (Figure 6D, tom70 $Delta$ ) and was only slightly impaired, inthe case of Tim9, by a deletion of TOM20 (Figure 6D, tom20 $Delta$ ).We wondered whether the small Tim proteins showed a requirementfor Tom5 as receptor because Tom5 is resistant to trypsin treatmentand can suffice as a receptor under bypass import conditions (Dietmeieret al., 1997). Indeed, the import of the small Tims was stronglyinhibited in tom5 $Delta$ mitochondria (Figure 6D, tom5 $Delta$ ). Previous workshowed that the tom5 $Delta$ mitochondria are selectively deficient inTom5, whereas the other Tom proteins are present in normal amountsand the GIP complex is not altered (Dietmeier et al., 1997; Dekkeret al., 1998). Although the import of preproteins in tom5 $Delta$ mitochondriais generally reduced compared with wild-type mitochondria (Dietmeieret al., 1997), the small Tim proteins showed an even strongerreliance on Tom5 for their import compared with Tim22 and Tim54(Figure 2). We conclude that Tom5, but not the trypsin-accessiblesurface receptors, plays an important role in the targeting ofthe small Tims intomitochondria.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERNCES

The biogenesis of the Tim proteins of the carrier import route neither follows one of the known major import pathways formitochondrial preproteins (Figure 7A, routes I and II) nor fitsinto a common new mechanism. Three different targeting principlesseem to be necessary to import the Tim components of the carrierroute (Figure 7B).

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Figure 7. Multiple targeting routes of preproteins into mitochondria. (A) Established pathways for presequence-containing preproteins and carrier preproteins. Presequence-containing preproteins (I) follow an import route that preferentially involves binding to Tom20, whereas carrier preproteins (II) preferentially bind to Tom70. The pathways converge at the general import pore (GIP) consisting of, among other components, Tom5 and Tom40. The pathways diverge after translocation across the outer membrane and use different Tim complexes: the Tim23-Tim17 core complex along with mt-Hsp70 and Tim44 for presequence-carrying preproteins and the carrier translocase for carrier preproteins. The requirement of mtHsp70 for the import of preproteins using pathway I, but sorted to the inner membrane, seems to be sequence dependent. (B) Three distinct routes for the biogenesis of Tim proteins of the carrier pathway. Shown are the main import routes that are used by the Tim proteins of the carrier pathway. The import of Tim54 and Tim22 uses different features of the presequence-carrying preprotein and carrier preprotein pathways to reach the same destination. The small Tims seem to preferentially require Tom5, but not the surface receptors, for their import.

The preprotein of Tim22 is the first preprotein found that preferentially uses the receptor Tom20 for targeting to the outermembrane but follows the Tim route for carrier proteins (Figure7B, route III). Tim22 is a quite hydrophobic protein and thereforewould have been a typical candidate for binding to Tom70 likethe carrier preproteins, but import signals in Tim22 that arenot yet defined direct the preprotein to Tom20, which usuallyfunctions as a receptor for presequence-containingpreproteins.

In contrast, Tim54 carries an amino-terminal noncleaved translocation sequence that is positively charged like mitochondrialpresequences, yet Tim54 preferentially depends on Tom70 for itstargeting to the outer membrane (Figure 7B, route IV). After translocationthrough the GIP, Tim54 then follows the typical route for presequence-containingpreproteins until it reaches the Tim23-Tim17 core complex. Theamino-terminal positively charged sequence of Tim54 is requiredfor translocation of the preprotein into the mitochondria, whereasinteraction with the outer membrane can occur without this sequence.This indicates that the remainder of Tim54, which includes twopredicted hydrophobic segments (Kerscher et al., 1997), containsa signal for its interaction with Tom70. Although carrying anabundance of positive residues, the amino-terminal sequence ofTim54 is not predicted to form an amphipathic $alpha$ -helix becauseof the presence of several helix-breaking prolyl residues, distinguishingthis sequence from typical mitochondrial presequences (Roise etal., 1986; Von Heijne, 1986) and providing an explanation forthe only weak dependence on Tom20. Tim54 branches from the mainimport route at the level of Tim23 before a strict requirementfor matrix Hsp70 becomes crucial. It has been observed that ahydrophobic signal anchor following the positively charged amino-terminalregion of a preprotein minimizes its requirement for mtHsp70.This is apparently due to the sorting/membrane insertion activityof the hydrophobic segment at an early stage of translocationof an unfolded preprotein (Glick et al., 1993; Voos et al., 1993;Stuart et al., 1994; Gärtner et al., 1995a, 1995b). In agreementwith this model, the first predicted hydrophobic segment of Tim54is located immediately after the positively charged sequence (Kerscheret al., 1997).

In an elegant series of experiments, Mihara and colleagues (Hachiya et al., 1995; Komiya et al., 1996, 1997) demonstratedthat cytosolic cofactors from rabbit reticulocyte lysate are importantdeterminants for the selection of import receptors by preproteins.By using purified preproteins and cytosolic chaperones, they showedthat preproteins bound to the mitochondrial import stimulationfactor are imported via Tom70 in an ATP-dependent reaction, whereaspreproteins interacting with cytosolic Hsp70 preferentially useTom20 in an ATP-independent manner. In agreement with these observationswe found that the import of Tim22 via Tom20 did not require cytosolicATP, whereas the import of Tim54 via Tom70 was ATP-dependent.Because we used complete rabbit reticulocyte lysate, the fullset of cytosolic chaperones was present during the import reaction,suggesting that the preproteins of Tim22 and Tim54 were boundto different chaperones before their delivery to the mitochondria.Some preproteins bound to Tom70 seem to be transferred to Tom20before their insertion into the GIP, i.e., they require both Tom70and Tom20 for import (Keil and Pfanner, 1993; Keil et al., 1993;Hachiya et al., 1995; Hönlinger et al., 1995a; Komiya et al.,1997), whereas other preproteins can be directly transferred fromTom70 to the GIP complex (Söllner et al., 1990; Steger et al.,1990). The preprotein of Tim54 mainly behaves like the latterpreproteins. Tim54 bound to Tom70 does not strictly need to betransferred to Tom20 but can be directly transferred to the GIPcomplex in the absence ofTom20.

A third and quite short import pathway is followed by the small Tim proteins (Figure 7B, route V). The small Tims are directlytranslocated into the intermembrane space without an insertioninto the inner membrane because their import does not requirean inner membrane potential. Other intermembrane space proteinsthat only use the Tom machinery are the cytochrome c heme lyaseand the cytochrome c₁ heme lyase. These preproteins strongly requireTom20 for their transfer to the GIP complex (Lill et al., 1992;Steiner et al., 1995). For the import of the small Tims, however,the trypsin-accessible surface domains of import receptors weredispensable, including Tom20, Tom22, and Tom70. Here, the trypsin-resistantTom5 that typically functions as the link between the receptorand the general import pore (Dietmeier et al., 1997) plays thecrucial role. Tom5 seems to represent the first Tom protein thatinteracts with the majority of preproteins of the small Tims.Besides the import of apocytochrome c (Stuart et al., 1990a,b),the import of the small Tims is therefore one of the simplestmitochondrial membrane translocation mechanisms known todate.

In addition to the various targeting pathways, this study led to two additional pieces of information. 1) Two new homologuesof the small Tims, termed Tim13 and Tim8, were identified andfound to be located in the intermembrane space. The four cysteinesthat were suggested to be of functional importance for the smallTims by formation of Zn-finger-like motifs are fully conservedin both Tim8 and Tim13. These small Tims were also identifiedindependently as mitochondrial intermembrane space proteins interactingwith Tim9 and Tim10 (Koehler et al., 1999). 2) Blue native electrophoresisprovides a simple and efficient method to assess the correct assemblyof in vitro imported Tim22 and Tim54 into a ~300-kDa complex.This complex also contains peripherally associated Tim12 (Koehleret al., 1998a,b; Sirrenberg et al., 1998; our unpublished results)and is termed the carriertranslocase.

In summary, we conclude that multiple mechanisms exist for targeting and membrane translocation of mitochondrial preproteins.Depending on the preprotein, distinct pieces of the known majorimport routes are combined to yield novel pathways. This includescrossing over of pathways at the level of the GIP complex of theouter membrane. For special preproteins like the small Tims, Tom5,which typically functions at the second or third stage of import,can become the first level import component and may thus havereceptor-likefunctions.

	ACKNOWLEDGMENTS

We thank Drs. Elizabeth Craig, Bernard Guiard, Michiel Meijer, and Falk Martin for yeast strains and preproteins, and Dr.Wolfgang Voos for helpful discussion. We are grateful to HanneMüller for expert technical assistance. This work was supportedby the Deutsche Forschungsgemeinschaft, Sonderforschungsbereich388 Freiburg, the Fonds der Chemischen Industrie, and a long-termfellowship from the Alexander-von-Humboldt Stiftung to M.T.R.

	FOOTNOTES

Corresponding author. E-mail address: pfanner{at}uni-freiburg.de.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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