(Received for publication, July 20, 1995; and in revised form, August 24, 1995)
From the
Membrane integration and assembly of MOM72 from Neurospora crassa and its yeast homolog MAS70 was studied with isolated mitochondria. After synthesis in vitro, the precursors of MOM72/MAS70 are tightly folded and expose only their N-terminal amino acid residues comprising the targeting and the membrane anchor domain. Insertion of the protein into the mitochondrial outer membrane (MOM) occurs in a time- and temperature-dependent manner and is stimulated by ATP. MOM72/MAS70 is then assembled into the outer membrane MOM complex. Whereas membrane insertion occurred independently of the presence of protease-sensitive surface components, the assembly reaction depended on such components. In the MOM complex MOM72 and MAS70 were found in the neighborhood of different components in yeast and N. crassa mitochondria. MOM72 was found in association with MOM22 in N. crassa mitochondria, whereas MAS70 was in proximity to a 37-kDa component in yeast outer mitochondrial membrane. The interaction with the 37-kDa protein is important for integration of MAS70 into the MOM complex. Thus, the 37-kDa protein plays an important role in the biogenesis of MAS70.
The protein transport machinery of the mitochondrial outer
membrane (MOM) ()consists of at least seven different
protein components. The MOM complex facilitates insertion and membrane
translocation of nuclear encoded mitochondrial proteins during their
import into the various subcompartments of the mitochondria. The
proteins present in the MOM complex fulfill distinct functions in the
transport process. In Neurospora and yeast, precursor proteins
interact through targeting signals with mitochondrial import receptors
MOM72, MOM19, and MOM22 at the cis-side of the outer
membrane(1, 2, 3, 4, 5) .
Most of the precursors become inserted into a so far only poorly
characterized pore that contains MOM38 and at least two other
components, MOM8 and MOM7 (6, 7) . The targeting
signals then interact with a component at the trans-side of
the outer membrane(5) . Further translocation of the precursor
protein across the outer membrane or integration into the outer
membrane follows.
The proteins of the MOM complex are all encoded in the nucleus, synthesized on cytoplasmic polysomes, and then post-translationally targeted to the mitochondrial outer membrane. More than one pathway exists for the targeting of the different MOM proteins to the mitochondrial outer membrane. The MOM19 preprotein requires for its import the pore component MOM38 but no protease-sensitive surface receptors(8) . In contrast, the import of MOM22 and MOM38/ISP42 preproteins is dependent on the surface receptors MOM19 and MOM72(9, 10) . After their import the MOM proteins are assembled into the MOM complex. It is unclear so far how these proteins are sorted and assembled into this complex and how they interact with each other.
In this study we have analyzed insertion and assembly of Neurospora crassa MOM72 and its yeast-homolog MAS70 into the outer membrane and the MOM complex. Their insertion into the mitochondrial outer membrane was found to be stimulated by cytosolic ATP and independent of trypsin-sensitive components of the outer membrane. On the other hand, the assembly of MAS70 into the MOM complex was dependent on trypsin-sensitive surface components. Assembled MAS70 interacts in the mitochondrial outer membrane of yeast with a 37-kDa protein, whereas MOM72 interacts in N. crassa mitochondria with MOM22. MAS70 appears to be integrated by the 37-kDa protein into the MOM complex.
Figure 1:
Efficient import in vitro and
insertion of MAS70 into the outer membrane. A, import of
MAS70. S-labeled precursor of MAS70 was imported into
yeast mitochondria for 2-30 min at 25 or 4 °C as described
under ``Experimental Procedures.'' Mitochondria were
reisolated and then analyzed by SDS-PAGE, fluorography, and laser
densitometry. B, membrane insertion of MAS70. Import of MAS70
precursor into mitochondria was performed for 30 min at 25 °C. Then
mitochondria were reisolated and afterwards subjected to alkaline
treatment with Na
CO
. Soluble and insoluble
material were separated by centrifugation for 30 min at 50,000
g. As control, reticulocyte lysate containing
S-labeled MAS70 was treated with
Na
CO
. Total imported precursor (Total), supernatants (Sup), and pellets (Pel) were then analyzed as in A. Mitochondria, the amount of import to mitochondria was set to
100%; Lysate, the total input of MAS70 precursor corresponds
to 100%.
Endogenous MOM72 and MAS70 expose a large C-terminal 60-kDa domain into the cytosol, which can be cleaved from the mitochondria by applying low concentrations of protease(19, 20) . We asked whether also the in vitro imported protein acquires this characteristic behavior. MOM72 or MAS70 were imported into mitochondria, and these were subsequently treated with trypsin. The 60-kDa domain was cleaved off from the imported proteins and released into the supernatant (Fig. 2). The cytosolic precursor protein in the reticulocyte lysate was almost completely resistant to proteolytic attack under these conditions (Fig. 2). Only at higher trypsin concentrations (above 20 µg/ml) was the 60-kDa domain quantitatively formed from the precursor (data not shown). Thus, the precursors of MOM72 and MAS70 exhibit a high protease resistance, in sharp contrast to most other precursors(21) . From these results we conclude that insertion into the outer membrane is accompanied by a conformational change and/or release of factors that influence the protease sensitivity of MAS70/MOM72.
Figure 2: Alteration of protease sensitivity of in vitro synthesized MAS70/MOM72 upon insertion into mitochondrial outer membrane. A, MAS70 precursor was imported into yeast mitochondria. B, MOM72 precursor was imported into N. crassa mitochondria. Afterwards mitochondria were reisolated and suspended in SEM (20 µl). The mitochondria were then treated with trypsin (0.5 or 1 µg/ml) for 15 min at 0 °C. In addition, reticulocyte lysates containing MAS70 or MOM72 precursor were diluted into SEM and then treated with trypsin. Samples were analyzed by SDS-PAGE, fluorography, and laser densitometry. The total amounts of imported precursor without trypsin-treatment and of input precursor in lysate (free MAS70/MOM72), respectively, were set to 100%.
Figure 3:
ATP
dependence of MAS70 import and interaction of MAS70 precursor with
cytosolic HSP70. A, stimulation of import of MAS70 into yeast
mitochondria by ATP. Yeast mitochondria (100 µg) and reticulocyte
lysate containing S-labeled MAS70 were treated with
apyrase (5 units/ml) to deplete ATP. Then the mitochondria and lysate
were diluted into import buffer (100 µl) containing oligomycin (20
µM) and atractyloside (5 µM) without or with
addition of ATP or GTP (3 mM). The import mixtures were
incubated for 10 or 30 min at 25 °C. Afterwards the mitochondria
were reisolated and analyzed as described in the legend to Fig. 2. B, interaction of the precursor of MAS70 with
cytosolic HSP70. Reticulocyte lysate containing MAS70 precursor was
incubated for 15 min at 4 °C without addition (+ATP)
or with apyrase (5 units/ml) to deplete ATP (-ATP).
Immunoprecipitation (in SEM buffer containing 50 mM NaCl and
3% (w/v) bovine serum albumin) was performed using antibodies directed
against cytosolic HSP70 (a gift of Dr. M. Harmey), MAS70, or preimmune
sera (Pre). MAS70 in immunoprecipitates was determined by
SDS-PAGE and fluorography.
Figure 4: Effect of protease pretreatment of mitochondria on the import of MAS70 and MOM72. Yeast or N. crassa mitochondria (2 mg/ml in SEM) were treated with trypsin or proteinase K (1-50 µg/ml) for 15 min at 0 °C. Then soybean trypsin inhibitor (5 mg/ml) or phenylmethylsulfonyl fluoride (1 mM) were added. Mitochondria were reisolated and suspended in import buffer. Yeast mitochondria were then incubated with MAS70 precursor, and N. crassa mitochondria were incubated with MOM72 precursor for 30 min at 25 °C and then analyzed as described under ``Experimental Procedures.'' 100% corresponds to the import of precursor into untreated mitochondria.
Figure 5:
Prevention of MAS70 assembly into the MOM
complex by pretreatment of mitochondria with trypsin. Mitochondria (1
mg/ml SEM) isolated from wild type (WT) or MAS70 (
70) cells were treated with trypsin (0.3-5
µg/ml). After the addition of soybean trypsin inhibitor (5 mg/ml),
the mitochondria were reisolated and MAS70 precursor was imported into
the mitochondria. Then mitochondria were reisolated. For assaying
insertion of MAS70, the mitochondria were subjected to carbonate
treatment. The assembly of MAS70 into the MOM complex was tested by
lysing the mitochondria in digitonin buffer and then performing
coimmunoprecipitation with anti-ISP42 antibodies. Inserted or
coimmunoprecipitated (assembled) MAS70 was analyzed by SDS-PAGE,
fluorography, and laser densitometry. The amount of inserted or
coimmunoprecipitated MAS70 from untreated mitochondria was set to
100%.
Figure 6: Interaction of MAS70 with components in the mitochondrial outer membrane. A, interaction of MAS70 in yeast mitochondria with a protein of 37 kDa. Import of MAS70 precursor into mitochondria was performed for 30 min at 25 °C. Then mitochondria were reisolated and suspended in SEM. The samples were incubated without or with EDC (0.5 mM) for 30 min at 0 °C (reactions 1 and 2). In addition reticulocyte lysates containing MAS70 precursor were incubated with or without EDC under the same conditions (reactions 3 and 4). Then Laemmli buffer was added to the reactions, and SDS-PAGE and fluorography were performed (reactions 1-4 correspond to lanes 1-4). B, cross-link of endogenous MAS70 with the 37-kDa component. Yeast mitochondria (200 µg in 200 µl SEM) were incubated with different concentrations of EDC (0.5-3 mM). Then the mitochondria were reisolated and analyzed by SDS-PAGE. Proteins were blotted on nitrocellulose and immunodecorated with antibodies directed against MAS70. C, prevention of cross-linking of MAS70 with the 37-kDa protein by trypsin pretreatment of yeast mitochondria. Mitochondria were treated with the indicated concentrations of trypsin. Then import of MAS70 precursor into mitochondria was performed as in A followed by cross-linking with EDC (1 mM). Proteins were analyzed by SDS-PAGE, fluorography, and laser densitometry. D, distinction of the cross-linked 37-kDa protein from ISP42. Import of MAS70 precursor into yeast mitochondria and reactions without and with EDC (0.5 mM) were performed as described in A (lanes 1 and 2). Then mitochondria were lysed in Triton X-100 buffer and immunoprecipitated with preimmune antibodies (Pre) or antibodies directed against ISP42 or MAS70. Immunoprecipitates were analyzed by SDS-PAGE and fluorography (lanes 3-8). x, cross-link of MAS70.
Cross-linking of MAS70 to the 37-kDa protein was abolished when mitochondria were pretreated with a concentration of 2 µg of trypsin/ml or higher (Fig. 6C). Thus, it appears that the 37-kDa protein either is a protease-sensitive component or assembly of MAS70 into the MOM complex is blocked in trypsin-treated mitochondria due to degradation of another component involved in assembly.
In order to exclude the possibility that the cross-linked protein was ISP42, immunoprecipitation with antibodies directed against ISP42 was performed, which quantitatively precipitated the ISP42 protein. The 37 kDa/MAS70 cross-linked species was not precipitated by these antibodies (Fig. 6D). We conclude that the 37-kDa protein is a protein in the yeast mitochondrial outer membrane, which is present in the immediate neighborhood of MAS70 and probably forms a complex with MAS70.
To determine whether also the cross-linked product MAS70-37 kDa is associated with the MOM complex, we used the coimmunoprecipitation procedure. Mitochondria in which MAS70 had been imported were treated with EDC and detergent-lysed, and then coimmunoprecipitation was performed with ISP42-specific antibodies (Fig. 7). The cross-linked product MAS70-37 kDa was precipitated by these antibodies. Interestingly, anti-ISP42 lead to a much more efficient precipitation of the MAS70-37 kDa cross-linked species than non-cross-linked MAS70. This enhanced coimmunoprecipitation of MAS70 indicates that ISP42 and the 37-kDa protein interact with each other (directly or indirectly) and that the 37-kDa protein recruits MAS70 into the MOM complex.
Figure 7: Coimmunoprecipitation of the MAS70-37 kDa cross-linked product with ISP42. Import of MAS70 and cross-linking with EDC was performed as in Fig. 6A. Then mitochondria were lysed in digitonin buffer. Coimmunoprecipitation with anti-ISP42 or anti-MAS70 antibodies was performed. Proteins in the immunoprecipitates were analyzed by SDS-PAGE and fluorography (lanes 1-4). Total protein was analyzed for comparison (lanes 5 and 6).
Figure 8: Interaction of MOM72 in N. crassa mitochondria with MOM22. A, MOM72 precursor was imported into N. crassa mitochondria. Then reisolated mitochondria were incubated without or with EDC (0.5 mM) for 30 min at 0 °C. As control reticulocyte lysate was also incubated without or with the addition of EDC. Samples were analyzed as in Fig. 6A. B, import of MOM72 precursor into mitochondria and cross-linking with EDC was performed as in A. After reisolation, the mitochondria were lysed in Triton X-100 buffer. Immunoprecipitation was performed using preimmune antibodies (Pre) or antibodies directed against MOM19, MOM22, or MOM72. Immunoprecipitates were analyzed by SDS-PAGE and fluorography. I, cross-link of MOM72 to MOM22; II, SDS stable dimer of MOM72, which is also observed with endogenous MOM72(6) .
Finally we asked whether MOM72 could be cross-linked to the yeast 37-kDa protein or vice versa if MAS70 could be cross-linked to N. crassa MOM22 after their import into mitochondria of the heterologous organism. Under the conditions described for Fig. 6, no cross-linked proteins of these molecular masses were observed (not shown), which indicates that assembly of MOM72 and of MAS70 in heterologous mitochondria may not follow the correct pathway.
In this report we investigated the biogenesis and assembly of MOM72 and MAS70 into the MOM complex. The efficient insertion of these proteins into mitochondrial membranes is stimulated by the addition of ATP. Such a stimulatory effect of ATP on the membrane insertion has been reported for most outer membrane proteins studied(23, 24, 25) . Components that are responsible for this ATP effect could be located either in the cytosol or at the mitochondrial surface(26) . Cytosolic factors known to stimulate the mitochondrial protein import in an ATP-dependent manner are cytosolic HSP70, Ydj1p, and the mitochondrial import stimulating factor(27, 28, 29) . We show that cytosolic HSP70 interacts in an ATP-dependent manner with the precursor form of MAS70. As the hydrophilic 60-kDa domain of MAS70 and MOM72 exists as a tightly folded domain, cytosolic HSP70 could bind to the N-terminal amino acid residues of the precursor form comprising the signal anchor domain. This interaction with HSP70 might help to prevent aggregation of the cytosolic precursor due to the presence of the hydrophobic segments of the signal anchor domain (30, 31, 32, 33) and in addition help to expose the signal anchor domain such that it can be recognized by the mitochondrial outer membrane.
Because the cytosolic domain of MOM72 and MAS70 is tightly folded in the cytosol, it is likely to be in its functional conformation(20) . Therefore folding of MOM72 in the cytosol is different from precursors of other outer membrane proteins, for example monoamine oxidase A. This latter protein changes its conformation from an inactive to an active conformation upon binding to the outer membrane as shown by inhibitor interaction(34) .
What are the mitochondrial components that control the insertion of outer membrane proteins into the lipid phase? For some outer membrane proteins it was shown that import receptors are involved in the insertion process. Two components of the MOM complex, MOM22 and MOM38, use both the receptors MOM19 and MOM72 for their binding to and insertion into the outer membrane(9, 10) . On the other hand, import of MOM19 is independent on surface receptors, such as pre-existing MOM19 or MOM72, but depends on MOM38(8) .
Experiments presented here suggest that protease-sensitive surface components are not essential for insertion of MOM72/MAS70 into the outer membrane. MOM22 does not influence the insertion of MOM72, because in a mutant, in which MOM22 is missing, import of MOM72 is not impaired(35) . Furthermore, the drastically reduced levels of MOM19 in this mutant indicate that MOM19 is not needed for the insertion of MOM72 into the outer mitochondrial membrane. The observation that anti-MOM19 IgG interferes with the import of MOM72 at low temperatures (3) might be related to a kinetic effect triggered by binding of the antibody to the MOM complex. Yet it could be that MOM38/ISP42 is involved in MOM72/MAS70 integration, although membrane insertion of MOM72/MAS70 was not impaired in protease-treated mitochondria in which MOM38/ISP42 was clipped by added protease. These cleavage products might retain insertion activity as was shown for the SecY protein in Escherichia coli(36) . Interestingly, a fusion protein between the MAS70 signal anchor and dihydrofolate reductase was not able to interfere with the import of matrix proteins(32) . This observation would indicate that for its membrane insertion MAS70 does not use the same entry site into the MOM complex as precursors destined for other subcompartments.
MAS70 assembles in the outer membrane into the MOM complex(3, 7, 8, 22) . The assembly step of MAS70 occurs at a stage that can be differentiated from the insertion step because pretreatment of mitochondria with trypsin did not influence insertion but abolished assembly into the MOM complex. Thus, proteinaceous components are needed for the assembly step to occur. This raises the question of which components are associated with MAS70 and MOM72 in the outer membrane. Using a cross-linking approach, we found MAS70 in the neighborhood of a protease-sensitive 37-kDa protein in the outer membrane of yeast mitochondria. In yeast the 37-kDa protein appears to be needed for the assembly of MAS70 by anchoring it to the MOM complex. The 37-kDa protein is so far uncharacterized. It could represent either a novel component or be identical to the protein MAS37, which is located in the mitochondrial outer membrane and was suggested to function in combination with MAS70(37, 38) . Another component that could correspond to the 37-kDa protein is MSP1 (apparent molecular mass of 40 kDa), an outer membrane ATPase that upon over-expression was reported to mislocalize a MAS70 fusion protein to the inner membrane (39) . We are currently investigating whether the 37-kDa protein is one of these proteins or a new outer membrane component.
In N. crassa mitochondria MOM72 was found in contact with MOM22. Recently, MOM19 was also reported to physically interact with MOM22 in N. crassa mitochondria(40, 41, 42) . Therefore, receptor and translocation sites for precursors appear to be in close proximity.
It is interesting to note that MOM72 and MAS70 do not
interact in yeast and Neurospora in the same manner with their
heterologous components as with their partners in the homologous
mitochondria. This observation would explain why MOM72 is not able to
complement the import and growth defect of a MAS70 mutant. (
)On the other hand, the N. crassa proteins MOM19
and MOM38 assemble properly into the yeast MOM complex in
vitro, and MOM19 does so in
vivo(8, 10, 22) . So far there is no
data to support that these proteins become functional in the yeast MOM
complex. However, because MAS22 of yeast could be cloned by
complementation with Neurospora MOM22(43) , such a
functional exchangeability might hold for other components of the MOM
complex.
From the experiments presented here we suggest the following model for the biogenesis of MAS70. Most likely insertion of MAS70 is mediated by interaction of its signal anchor domain with the general insertion pore, followed by insertion of the protein into the outer membrane. For assembly into the MOM complex, MAS70 then needs to interact with the cytosolic exposed part of a 37-kDa protein, which is located in the yeast mitochondrial outer membrane.
In summary, we showed that assembly into the MOM complex but not membrane insertion of MAS70 is dependent on trypsin-sensitive mitochondrial surface components. In the MOM complex, MAS70 and MOM72 are in contact with specific components that are a 37-kDa protein in yeast and the protein MOM22 in N. crassa. The interaction with the 37-kDa protein likely anchors MAS70 to the MOM complex and therefore might be essential for the assembly of MAS70.