Ribosome Binding to Mitochondria Is Regulated by GTP and the Transit Peptide*

Kathleen S. Crowley and R. Mark PayneDagger

From the Department of Pediatrics, Wake Forest University School of Medicine, Winston-Salem, North Carolina 27157-1081

    ABSTRACT
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Abstract
Introduction
Materials & Methods
Results
Discussion
References

The association between ribosomes and the pore proteins at the endoplasmic reticulum membrane is important to co-translational translocation. To determine if a similar association occurs between the ribosome and mitochondrial membrane protein(s) during protein import in higher eukaryotes, we examined ribosome-mitochondria binding. By using spectral measurements, analysis of mitochondrial associated RNA, and electron microscopy, we demonstrated that ribosomes stably bind to purified rat liver mitochondria in vitro. Binding of ribosomes to mitochondria was markedly reduced by GTP and nearly abolished by the non-hydrolyzable GTP analogue, guanosine-5'-[thio]-triphosphate (GTPgamma S), but was only modestly reduced by GDP or ATP and unaffected by CTP. The initial rate of GTP hydrolysis by mitochondria was increased by ribosomes, whereas the rate of ATP hydrolysis by mitochondria was not affected. Ribosomes programmed with mRNA for 92 amino acids of the N terminus of mitochondrial malate dehydrogenase bound to mitochondria, but unlike unprogrammed rat liver ribosomes, neither GTP nor GDP disrupted binding; however, GTPgamma S did. These data show that receptors specific for ribosomes are present on the mitochondrial membrane, and a GTP-dependent process mediates this binding. The presence of a nascent chain alters these binding characteristics. These findings support the hypothesis that a co-translational translocation pathway exists for import of proteins into mitochondria.

    INTRODUCTION
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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Proteins can cross membranes by either post-translational or co-translational translocation. Based on in vitro observations, proteins targeted to the mitochondria are thought to be completely synthesized in the cytoplasm and cross the mitochondrial membrane(s) post-translationally (1). However, evidence consistent with a co-translational translocation pathway for mitochondrial protein import has been reported. For example, 1) the surface of mitochondria isolated from cycloheximide-treated yeast cells is observed to be studded with polysomes (2); 2) the number of bound polysomes is dependent on the metabolic state of the cells from which the mitochondria are isolated (3); 3) ribosomes are bound to the mitochondria at the contact sites (4); and 4) the mRNA of polysomes that co-isolate with mitochondria is enriched in messages for mitochondrial proteins (5, 6). In addition, both in vitro and in vivo, mitochondrial protein import can be instantaneously disrupted by cycloheximide-induced translation arrest indicating that no detectable pool of full-length precursor exists in the cytosol and that translation and import are tightly coupled (7-9). Furthermore, methotrexate, which inhibits post-translational import of cytochrome oxidase subunit IV-dihydrofolate reductase by preventing its unfolding, does not inhibit cytochrome oxidase subunit IV-dihydrofolate reductase import in vivo (9). This indicates that co-translational translocation may eliminate the need for precursor proteins to be maintained in a translocation-competent state by chaperones in the cytoplasm.

Almost all mitochondrial matrix and inner membrane proteins are synthesized with an N-terminal presequence and then imported into the mitochondria (10-12). The presequence-containing precursor protein is presumably held in a translocation-competent conformation in the cytoplasm by hsp70 chaperonins probably in concert with the presequence-specific chaperonin, e.g. "targeting factor" or mitochondrial stimulating factor, and the precursor is recognized and imported by a multisubunit translocation complex in the mitochondrial membranes (13-18). Since these early events in targeting and translocation clearly and specifically involve the N-terminal presequence, it is entirely possible that mitochondrial protein import can be initiated long before translation is complete.

To examine the hypothesis that, in vivo, proteins import into the mitochondria by a co-translational translocation pathway, and to determine whether receptor(s) for the translation machinery at the outer membrane play a role in targeting an incompletely synthesized nascent polypeptide chain to the mitochondrial import site, we examined the interaction of the ribosome with the mitochondria. Specifically, ribosome binding to mitochondria was shown using three independent methods, and the ability of ribosome-bound nascent polypeptide chains to target the ribosome to the mitochondria was determined. Finally, because recent studies have shown that GTP-binding proteins are not only involved in initiating protein translocation at the membrane of the endoplasmic reticulum (ER),1 but are also involved in protein import into chloroplast (19), we determined the effect of ATP and GTP on ribosomes binding to mitochondria and the early events in protein translocation.

    MATERIALS AND METHODS
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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Preparation of Ribosomes and Rough Endoplasmic Reticulum-- Ribosomes and rough endoplasmic reticulum (RER) were isolated from the post-mitochondrial supernatant of rat liver homogenates by a previously described method (20). To remove endogenous GTPase activity, isolated ribosomes were resuspended in 50 mM Tris, pH 7.4, 0.5 M KOAc, 10 mM MgCl2, and 4 mM dithiothreitol containing 1 unit/µl RNasin (Promega), incubated at room temperature 15 min, and re-isolated by sedimentation through a 0.5 M sucrose cushion containing 0.5 M KOAc, 50 mM Tris, pH 7.6, 5 mM MgOAc, 4 mM dithiothreitol, 1 unit/µl RNasin. Rabbit reticulocyte ribosomes were isolated as described (21). The final ribosomal pellets were resuspended in ribosome binding buffer (RB, 50 mM Tris, pH 7.4, 100 mM KOAc, 10 mM MgCl2, 1 mM dithiothreitol containing 1 unit/µl RNasin) and stored at -70 °C in small aliquots.

Preparation of High Salt-washed Mitochondria-- Mitochondria were isolated from Sprague-Dawley rat livers using previously published methods (22). Mitochondria were further purified to reduce ER contamination using metrizamide-Percoll density gradient centrifugation as described previously (23). Final preparations were brought to a protein concentration between 5 or 15 mg/ml in 10 mM Tris, pH 7.4, 70 mM mannitol, and 250 mM sucrose (MIB) and either used immediately or flash-frozen in liquid nitrogen and stored at -70 °C. Ribosome binding activity and GTP hydrolysis was essentially the same for fresh and previously frozen mitochondria, although electron microscopy indicated integrity of the intermembrane was often disrupted in the previously frozen mitochondria. Mitochondria were washed using a previously described method for stripping ER membranes of ribosomes (24). For all experiments described, EDTA, high salt-washed mitochondria (EKMT) were used unless otherwise specified.

Enzyme Assays-- Glucose-6-phosphatase activity and arylesterase activity were measured as described previously (25, 26, respectively). The amount of inorganic phosphate (Pi) produced from trinucleotide hydrolysis by mitochondria and ribosomes was determined using a modification of a previously described method (27). Briefly, 17-µl samples were prepared as described above, and after incubation and pelleting, the supernatants were brought to 500 µl with water and 100 µl of 7.5 N H2SO4, 100 µl of 6.6% (NH4)6Mo7O24·4H2O, and 80 µl of freshly prepared 0.36 M FeSO4·7H2O, 0.15 N H2SO4 were added sequentially. After a 20-min incubation, the absorbance was measured at 650 or 700 nm. To correct for light scattering, Pi contamination, and/or nucleotide degradation, background samples containing ribosomes, mitochondria, or ribosome-mitochondria complexes but lacking nucleotides, as well as samples containing only nucleotides, were run in parallel, and their absorbance was subtracted from the corresponding samples.

Preparation of Ribosome-Nascent Chain Complexes-- Rat mitochondrial malate dehydrogenase (mMDH) mRNA was synthesized by in vitro transcription of linearized pGEM-mMDH as described previously (22). Plasmids were cleaved in the mMDH coding region with FokI, and truncated mMDH mRNAs produced by in vitro transcription were translated in nuclease-treated rabbit reticulocyte lysate (Promega) in the presence of [35S]methionine to produce stable ribosome-nascent chain complexes carrying peptides of defined length (28). The TNT® T7 luciferase control plasmid was cleaved in the coding region with Cfr10, and ribosome-nascent chain complexes were produced using the TNT®-coupled transcription/translation reticulocyte lysate system as recommended by the supplier (Promega). Ribosome-nascent chain complexes were isolated as described (21) except the ribosomes were not high salt- washed and the sucrose cushion contained 100 mM KOAc instead of 500 mM KOAc.

Ribosome-Mitochondria Binding Assay-- Before each binding assay, ribosomes were centrifuged at 17,000 × g for 2 min to remove insoluble material. Mitochondria (75-300 µg as indicated) and ribosomes (2-16 µg as indicated) were mixed in a total reaction volume of 17 or 25 µl of RB/MIB (1:3). Either ATP, GTP, GDP, GTPgamma S, or CTP was added to a final concentration of 1.2 mM as indicated. Samples were incubated for 0-15 min at room temperature, and mitochondria were immediately sedimented at 17,000 × g for 2 min. The mitochondrial pellets were washed with MIB and resuspended in MIB containing 1 mM MgCl2, and the absorbance of the supernatant and/or mitochondrial suspension was measured at 260 and 280 nm for each sample. In parallel, samples containing only mitochondria and nucleotide were assayed and set as background for the corresponding ribosome, mitochondria, and nucleotide sample. When ribosomes carried [35S]methionine-labeled nascent chains, the relative amount of ribosome-nascent chain complex binding was also determined by liquid scintillation counting of the ribosome-mitochondrial pellet.

To verify that absorbance changes of the resuspended mitochondrial pellets reflected differential ribosomal binding, 400-450 µg of mitochondria were incubated with approximately 75 µg of ribosomes in 200 µl of RB/MIB (1:3) for 5 min at room temperature. The ribosome-mitochondria complexes were divided into 30-µl aliquots, sedimented (10,000 × g, 5 min, 4 °C), and resuspended in 30 µl of RB/MIB (1:3) containing either 0.1 or 5 mM ATP, GTP, GDP, GTPgamma S, CTP, or no nucleotide. Samples were again incubated at room temperature for 5 min and sedimented through an equal volume of 1.0 M sucrose cushion (10,000 × g, 5 min, 4 °C). Pellets and supernatants were extracted with phenol/chloroform/isoamyl alcohol (25:24:1) and the RNA ethanol-precipitated. The resuspended RNA was subjected to both agarose gel electrophoresis and dot blot analysis, using a [32P]dCTP-radiolabeled 300-nucleotide cDNA probe that had been amplified by polymerase chain reaction using cytoplasmic 18 S rRNA as a template (GenBankTM accession number V01270. Sense primer, 5'-TACATGCCGACGGGCGCTGACC-3'; antisense primer, 5'-CCTGCTGCCTTCCTTGGATG-3'). The 18 S probe was tested by Northern blot analysis to confirm that the RNA visualized by ethidium bromide staining corresponded to cytosolic 18 S rRNA and not mitochondrial rRNA.

Electron Microscopy-- Samples were prepared for electron microscopy by adding 100 µl of mitochondria or ribosome-mitochondria complexes (approximately 7.5 µg of mitochondrial protein/µl) to 1 ml of fixative containing 4% glutaraldehyde, 100 mM sucrose, 100 mM cacodylate buffer, pH 7.4 (glutaraldehyde/sucrose/cacodylate buffer). Fixed samples were washed with 100 mM sucrose, 100 mM cacodylate buffer, pH 7.4, postfixed in 1% OsO4, and dehydrated in graded ethanols. Samples were embedded in Spurr's resin (29), thin sectioned, and examined using a Philips 400 TEM operating at 80 KeV (Micromed, Wake Forest University School of Medicine). Ten randomly selected fields for mitochondria under each condition were photographed at a magnification of × 15,200, and the number of ribosomes per field was counted by hand. To ensure that each field had the same amount of mitochondrial surface area, point count stereology was used to quantify the relative surface areas of en face versus cross-sectional views of mitochondria (30). Between all fields in all conditions, this ratio was very constant at 0.31 to 0.33, and thus, absolute numbers of ribosomes are reported for comparison between fields. For each condition, the fields with the highest and lowest counts of ribosomes were discarded, and the average and standard deviation of the remaining eight fields are reported.

    RESULTS
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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Ribosomes Bind to Mitochondria-- Rat liver mitochondria prepared by differential centrifugation have been shown to contain other organelles including a significant amount of rough endoplasmic reticulum-derived microsomes (26). In order to examine only the ribosome-mitochondria interaction, crude mitochondrial preparations were either subjected to EDTA and high salt treatment (24), purification by density gradient centrifugation (23), or both. All preparations were analyzed for activity of the RER-specific enzymes, glucose-6-phosphatase, and arylesterase. Based on enzyme activity, either density gradient centrifugation (MPMT) or EDTA/high salt treatment of mitochondria (EKMT) reduced the amount of RER contamination by about 75%, whereas density gradient centrifugation followed by EDTA/high salt treatment (EKMPMT) essentially eliminated RER contamination (Fig. 1).


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Fig. 1.   Enzyme activity. Glucose-6-phosphatase (B) and arylesterase (A) activities were determined on preparations of endoplasmic reticulum, ribosomes, and mitochondria. Each solid bar represents the mean of at least three separate experiments. Error bars represent the standard deviation. MT, mitochondria from differential centrifugation; MPMT, metrizamide/Percoll-purified mitochondria; EKMT, EDTA/high potassium salt washed mitochondria; EKMPMT, EDTA/high-salt, metrizamide/Percoll-purified mitochondria; RER, rough endoplasmic reticulum.

Prior to conducting ribosome-mitochondria binding experiments, cytosolic rat liver ribosomes were washed in high salt to remove endogenous GTPase activity and were tested for inorganic phosphate production from GTP or ATP. The initial rate of GTP hydrolysis by ribosomes was reduced approximately 80% by high salt treatment (Table I). Ribosomes preparations were also analyzed for RER enzyme markers and were shown to be free of RER contamination (Fig. 1).

                              
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Table I
Phosphate production
Each value listed represents the mean ± S.D. from at least three experiments. Each assay included 150 µg of EDTA/high salt-washed mitochondria, 5 µg of ribosomes, and 1.2 mM nucleotides.

High salt-washed ribosomes were incubated with EDTA/high salt-washed, density gradient purified mitochondria (EKMPMT); the ribosome-mitochondria complexes were separated from free ribosomes by sedimentation, and the A260 of resuspended complexes and/or the free ribosomes remaining in the supernatant were measured. The difference in the A260 between resuspended mitochondria incubated without ribosomes and mitochondria incubated with ribosomes was taken to represent ribosome binding. As shown in Fig. 2, ribosomes bind to both freshly isolated and previously frozen mitochondria. The number of ribosomes bound per mg of mitochondria is much higher in the previously frozen samples, presumably because the mitochondrial contents leak out of the mitochondria upon freeze-thawing. Freshly isolated mitochondria will bind approximately one ribosome per 1.7 fg of mitochondrial protein when saturated with ribosomes (Fig. 2).


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Fig. 2.   Binding of ribosomes to mitochondria. EDTA/high salt- washed mitochondria (150 µg) were incubated with high salt-washed ribosomes (2-16 µg corresponding to a final concentration of 19-160 nM) in 25 µl. Identical samples without ribosomes were incubated in parallel, and the A260 of each ribosomal concentration was also measured. After 5 min, the ribosome-mitochondria complexes, or mitochondria controls, were sedimented, and the supernatants were brought to 350 µl in 50 mM Tris, pH 7.4, 100 mM KOAc, 10 mM MgCl2, and their absorbance was measured at 260 nm. For each condition, the A260 of the mitochondria incubated without ribosomes was subtracted from the A260 of the mitochondria incubated with ribosomes. Data were subjected to a one-site binding analysis which calculated a binding maximum of 9.6 ± 0.9 pmol/mg, r2 = 0.9748, for freshly isolated mitochondria.

Because ATP is required for post-translational import of proteins into the mitochondria and because GTP is required for co-translational translocation of protein into the ER, we hypothesized that nucleotides would alter ribosome binding to mitochondria. Formation of ribosome-mitochondria complexes was measured as before except samples were initially incubated with or without ATP, GTP, GDP, GTPgamma S, or CTP. A differential increase in the A260 and A280 resulting in an increased A260/A280 ratio (Table I) was observed when resuspended mitochondria had been incubated with ribosomes compared to when resuspended mitochondria had been incubated alone. This indicates that the ribonucleic acid-containing ribosomes associate with mitochondria, and the increase in the A260 was arbitrarily set to represent 100% ribosome binding (Fig. 3, lane MR). Similar increases in the A260 and A280 were observed when 1.2 mM CTP was included in binding assay (Fig. 3, lane MRCTP). However, when 1.2 mM GTP or GTPgamma S was included, only minimal increases in absorbance were observed (Fig. 3, lanes MRGTP and MRGTPS). Inclusion of GDP or ATP in the binding assay resulted in A260 increases that were somewhat lower than values obtained in the absence of nucleotide but were also significantly higher than GTP and GTPgamma S. This indicates that the association between ribosomes and mitochondria can be blocked by GTP or GTPgamma S but is only mildly affected by ATP or GDP. Under the conditions used here, it is unclear if the effect of ATP on binding is direct or a result of conversion of ATP to GTP from existing GDP. However, the dramatic effects of GTP or GTPgamma S on complex formation was statistically different from complex formation under all other conditions tested indicating that GTP plays a dominant role in controlling the ribosome-mitochondria association.


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Fig. 3.   The effect of nucleotides on ribosome-mitochondria interaction. EDTA/high salt-washed mitochondria (EKMT) (75 or 150 µg) were incubated with high salt-washed ribosomes (5 µg) in the absence and presence of 1.2 mM ATP, GTP, GDP, GTPgamma S, or CTP, all in 17 µl. Identical samples without ribosomes were incubated in parallel. After 5 min, the ribosome-mitochondria complexes, or mitochondria controls, were sedimented, and pellets were resuspended in 50 mM Tris, pH 7.4, 100 mM KOAc, 10 mM MgCl2, and the absorbance was measured at 260 nm. For each condition, the A260 of the mitochondria incubated without ribosomes was subtracted from the A260 of the mitochondria incubated with ribosomes. This is graphed as the change in A260 for each condition divided by the change in A260 when ribosomes are bound to mitochondria in the absence of nucleotide and represents the relative amount of ribosomes bound to mitochondria. MR, mitochondria and ribosomes; MRATP, mitochondria, ribosomes, and ATP; MRGTP, mitochondria, ribosomes, and GTP; MRGDP, mitochondria, ribosomes, and GDP; MRGTPS, mitochondria, ribosomes, and GTPgamma S; MRCTP, mitochondria, ribosomes, and CTP. The data represent the average of at least three experiments and were subjected to one-way analysis of variance. * indicates significant difference (p < 0.05) from mitochondria and ribosomes.

To confirm that the increases in the A260 and the A280 for mitochondria incubated with ribosomes were due to ribosome-mitochondria binding, ribosome-mitochondria complexes were pre-formed by incubation of EKMPMT with high salt-washed ribosomes in the absence of nucleotides. The pre-formed complexes were isolated by sedimentation, and the pellets were resuspended in RB/MIB containing either no nucleotide, GTP, GDP, GTPgamma S, or ATP at a concentration of either 0.1 or 5 mM. Complexes were re-isolated by sedimentation, and to assess whether ribosomes remained bound under each condition, the relative amount of rRNA in the supernatants and pellets was determined by subjecting the extracted samples to agarose gel electrophoresis followed by ethidium bromide staining or by dot blot analysis (Fig. 4). Ribosomal RNA extracted from the pellet represents the stably bound ribosomes, whereas rRNA in the supernatant represents ribosomes that were released from the mitochondria.


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Fig. 4.   GTP destabilizes ribosome-mitochondrial binding. EDTA/high salt-washed mitochondria (EKMT) (approximately 450 µg) were incubated alone or with ribosomes (75 µg) to form mitochondria-ribosome complexes. The 30 µl of mitochondria and mitochondria-ribosome complexes were sedimented and resuspended in RB/MIB (50 mM Tris, pH 7.4, 100 mM KOAc, 10 mM MgCl2, 10 mM Tris, pH 7.4, 70 mM mannitol, and 250 mM sucrose; 1:3) alone, or RB/MIB containing GTP, GDP, GTPgamma S, or ATP. After 5 min at room temperature, mitochondria and complexes were re-sedimented, and the rRNA was extracted from supernatants and pellets and was subjected to either 1% agarose gel electrophoresis or dot blot analysis. A, the rRNAs were visualized by ethidium bromide staining. Shown are the 28 S and 18 S rRNA remaining with mitochondrial pellets when no nucleotide was incubated (-NTP) or when 5 mM GTP, GDP, GTPgamma S, or ATP, respectively, was incubated with pre-formed mitochondria-ribosome complexes for 5 min. B, supernatants from samples corresponding to those in A were subjected to RNA dot blot analysis to quantify and confirm that differences in mitochondrial-associated rRNA were the result of ribosome release and not degradation. The dot blot was probed with [32P]dCTP-labeled cDNA for a portion of the 18 S rRNA. Dots were quantified using an AMBIS radiometric counter, and the cpm for each condition were plotted.

When no nucleotide was added to the pre-formed complexes, nearly all rRNA re-sedimented with the mitochondria (Fig. 4, A and B, lane -NTP). Again, this indicates that the ribosomes remained stably bound to mitochondria in the absence of nucleotide. As expected, pellets obtained from pre-formed ribosome-mitochondria complexes incubated with GTP, GDP, or GTPgamma S contained less rRNA demonstrating that guanine nucleotides selectively disrupt binding (Fig. 4A, lanes GTP, GDP, and GTPgamma S). ATP did not significantly disrupt binding under these conditions, and the effect of GDP on binding was considerably less than GTP. These differences were observed even at low concentration (0.1 mM) of GTP (data not shown). Samples containing mitochondria alone were treated exactly as the ribosome-mitochondria complexes and subjected to dot blot analysis in parallel, but no radioactivity was detectable for these samples. In agreement with spectral data, GTP and GTPgamma S have the greatest effect on ribosome-mitochondrial complex stability. These data show that 1) the spectroscopic absorbance changes correlate well with changes in ribosome binding, and 2) the ribosome-mitochondrial interaction is not the result of nonspecific binding since, when ribosome-mitochondria complexes are pre-formed, this interaction can be specifically reversed by GTP or GTPgamma S.

Finally, to confirm that the spectral data and dot blot analysis measured ribosome-mitochondria binding and not another process, such as ribosome aggregation and de-aggregation, ribosome-mitochondria complexes were examined by electron microscopy. Frozen unwashed mitochondria were thawed and washed twice in MIB. An aliquot was removed and fixed in glutaraldehyde/sucrose/cacodylate buffer. The remaining mitochondria were then EDTA/high salt-washed (EKMT) and an aliquot of these mitochondria was removed and fixed. Ribosomes were then added to the rest of the sample, and the sample was incubated for 5 min at room temperature. An aliquot was then removed, and the ribosome-mitochondria complexes were sedimented, washed in MIB, and fixed as before. The remaining sample was divided into 2 aliquots, and GTP was added to one of the aliquots at a final concentration of 1 mM. These two samples were incubated for 5 min, sedimented, washed in MIB, and then fixed.

As shown in Fig. 5A, ribosomes are bound to the mitochondrial membrane surface prior to EDTA/high-salt treatment. EDTA/high salt-washed mitochondrial membranes are devoid of ribosomes (Fig. 5B), but when ribosomes are added to these mitochondria, ribosomes again bind to the mitochondrial membrane surface (Fig. 5A, compare panels B and C). Finally, when GTP is added to the ribosome-mitochondria complexes, the number of ribosomes associated with the mitochondrial surface is markedly reduced compared with ribosome-mitochondria complexes before addition of GTP (Fig. 5A, compare panels C and D) or compared with ribosome-mitochondria complexes incubated without GTP (data not shown). To quantify these observed differences in ribosome binding, we counted the number of ribosomes binding to mitochondria from 10 random fields of all four conditions. Fig. 5B, lanes A and B, demonstrates that the observed differences in ribosome binding from Fig. 5A is real and that there is a statistically significant difference between panels C and D. Thus, these data show that ribosomes co-isolating with mitochondria remain bound to the mitochondrial surface even after freeze-thawing but that these ribosomes can be completely removed by EDTA/high salt treatment. EDTA/high salt treatment, however, does not cause mitochondria to lose their ability to bind ribosomes (panel C). Finally, GTP is very effective at removing ribosomes from the mitochondrial surface and clearly disrupts the ribosome-mitochondrial interaction (panel D).


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Fig. 5.   Electron micrographs of mitochondria and ribosome-mitochondria complexes. Panel A, endogenous rat liver ribosomes (arrow) remain bound to mitochondria after freezing and thawing. Panel B, however, mitochondria are essentially free of ribosomes after EDTA/high-salt treatment (EKMT). Panel C shows that when total ribosomes, isolated from rat liver, are added back to EKMT, the ribosomes (arrow) are again seen on the mitochondrial membranes. Finally, in panel D, addition of GTP to these complexes eliminates almost all ribosomes from the mitochondrial surface. The bar represents 1 µm. B, the average number of surface-bound ribosomes/220 µm2 and the standard deviation for each condition represented in lanes A-D were plotted. With respect to ribosomes binding to EKMT, C and D are significantly different. M, mitochondria isolated by differential centrifugation (lane A); EKM, mitochondria that have been EDTA/high salt-washed (lane B); R-EKM, ribosomes added back to EKM (lane C); R-EKM-G, GTP added to R-EKM (lane D).

In summary, we have used three different experimental approaches to independently prove that ribosomes specifically bind to mitochondria. These data also show that the interaction is affected by GTP and is reversible, providing strong evidence that this interaction is physiologically significant.

The Ribosome-Mitochondria Interaction Affects GTP Hydrolysis-- Because the presence of nucleotide had a marked effect on ribosome-mitochondria binding, we hypothesized that nucleotide hydrolysis was associated with this binding. The amount of inorganic phosphate (Pi) produced on the cytosolic side of isolated mitochondria was quantified in the absence and presence of ribosomes and nucleotides (Table I). Following sedimentation of the mitochondria, essentially no Pi was detected in the supernatants from EKMT, high salt-washed ribosomes, or ribosomes and EKMT together, when incubated without a trinucleotide. In addition, very little Pi was produced when EKMT, ribosomes, or ribosomes and EKMT together were incubated with GTPgamma S (Table I). In contrast, Fig. 6 shows the curve for Pi produced from GTP by EKMPMT, in the absence and presence of ribosomes. The initial rate of hydrolysis of GTP by mitochondria alone was 20 nmol/min/mg but was much higher at 85 nmol/min/mg for mitochondria and ribosomes together. Since ribosomes had no GTPase activity, acceleration of Pi production by mitochondria in the presence of ribosomes is due to the interaction between mitochondria and ribosomes increasing the rate of GTP hydrolysis. The rate of Pi production in the presence of ATP and, therefore, the rate of ATP hydrolysis by mitochondria in the presence of ribosomes, is approximately equal to the sum of the individual rates of Pi production by mitochondria and ribosomes alone indicating that the ribosome-mitochondria interaction does not affect the rate of ATP hydrolysis (Table I). Thus, the ribosome-mitochondrial interaction stimulates GTP hydrolysis which suggests this is a specific receptor-ligand interaction that is controlled by a GTP-dependent step.


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Fig. 6.   GTP hydrolysis by mitochondria alone or in the presence of ribosomes. The amount of inorganic phosphate produced from GTP (1.2 mM) by EDTA/high salt-washed, metrizamide/Percoll-purified mitochondria (EKMPMT) (Mito, 150 µg, open circle ), ribosomes (Ribo, 10 µg, square ), and EKMPMT and ribosomes incubated together (Mito. + Ribo., bullet ) in a total volume of 17 µl was measured at 2, 5, 10, and 15 min. Each point listed represents the mean value from three or more experiments. The curves indicate the best fit of the data to a hyperbolic nonlinear regression.

Interaction of Programmed Ribosomes with Mitochondria-- The presence of ribosome-binding sites on the mitochondria suggested that ribosome-mitochondrial binding might be functionally important in co-translational translocation. At physiologic concentrations of GTP, however, ribosomes isolated from the post-mitochondrial cytosol did not stably bind to mitochondria. Since the transit peptide is responsible for targeting a mitochondrial protein in the post-translational import pathway, we proposed that a nascent chain containing a mitochondrial transit peptide would be capable of directing the ribosome to the mitochondria and stabilize binding in the presence of GTP, whereas ribosomes carrying non-mitochondrial nascent chains would behave like unprogrammed ribosomes in the presence of GTP.

Ribosomes protect about 40 of the most recently added C-terminal amino acids of the growing polypeptide chain from macromolecules of the cytosol but allow exposure of the N-terminal end of the nascent polypeptide to the cytosol prior to complete translation (31). A truncated mRNA lacking a stop codon and containing the coding region of the N-terminal end of precursor mMDH was designed to minimize exposure of the mature portion of mMDH while allowing complete exposure of the transit peptide to the cytosol (32). The mRNA for this 92-amino acid polypeptide was translated using [35S]methionine in rabbit reticulocyte lysate, and the ribosome-nascent chain complexes were isolated by sedimentation, and the complexes were assayed for EKMT binding activity in the absence or presence of di- or trinucleotides. An 86-amino acid nascent luciferase polypeptide was used as a non-mitochondrial, targeted protein control and was produced similarly to the mMDH precursor.

The results of these experiments are summarized in Fig. 7 and show that when the ribosomes carry a mitochondrial transit peptide-containing nascent chain, the presence of GTP does not significantly reduce the amount of ribosome-nascent chain complexes bound to the mitochondria compared with the amount of ribosome-nascent chain complexes bound when no nucleotide is present (Fig. 7A). Similarly, when GDP was included, the number of ribosome-nascent chain complexes bound to mitochondria was not significantly different from the number of complexes bound in the absence of nucleotide. However, the presence of GTPgamma S greatly reduced the formation of stable ribosome-mitochondria complexes. These results differ from our earlier findings using unprogrammed ribosomes that showed that GTP caused a significant reduction in stable ribosome-mitochondria complex formation. In addition, the ribosomes carrying the non-mitochondrial luciferase nascent chains behave like unprogrammed ribosomes (Fig. 7B) and do not stably bind to mitochondria in the presence of either GTP or GTPgamma S. Thus, the presence of the transit peptide blocks GTP-dependent release of the ribosome from the mitochondria and allows stable formation of a ribosome-nascent chain-mitochondrial complex.


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Fig. 7.   Binding of mMDH ribosome-nascent chain complexes and luciferase ribosome-nascent chain complexes to mitochondria. The first 92 amino acids of mMDH and the first 86 amino acids of luciferase gene were translated in the presence of [35S]methionine. Ribosome-mitochondria complexes containing mMDH (A) or luciferase (B) were prepared by incubating isolated ribosome-nascent chain complexes for 5 min at room temperature with 75 or 150 µg of EDTA/high-salt mitochondria (EKMT) in the presence of the indicated nucleotide (1.2 mM) and a total volume of 17 µl. Ribosome-nascent chain-mitochondria complexes were sedimented and resuspended in 350 µl of 50 mM Tris, pH 7.4, 100 mM KOAc, 10 mM MgCl2, and the A260 (solid bars) and cpm (open bars) were measured. M92, ribosome-mMDH 92-mer-mitochondria complexes; L86 = ribosome-luciferase 86mer-mitochondria complexes. Data were standardized by setting the value of (mitochondria-ribosome) minus (mitochondria) at 100% bound. Relative binding in the presence of nucleotide was then calculated as follows: ((M + N + R) - (M + N)) div  ((M + R) - (M)), where M is EKMT, R is ribosome, and N is nucleotide. A represents the averaged data from at least three experiments and was subjected to one-way analysis of variance. * indicates significant difference from M92 (p < 0.05). B represents the averaged data of at least two experiments and was subjected to one-way analysis of variance. * indicates significant different (p < 0.05) from L86.

These experiments show that the transit peptide causes selective stabilization of ribosome-mitochondria binding in the presence of GTP and suggest a mechanism for selective import in the presence of a nonselective ribosome receptor; unprogrammed ribosomes and ribosomes programmed with non-mitochondrial proteins are not stably bound to the mitochondrial membrane. Additionally, it is clear that in the presence of ribosomes, the transit peptide alone is not capable of directing the nascent polypeptide to the mitochondria since the non-hydrolyzable GTPgamma S destabilizes this binding. A GTP-dependent process, therefore, must function in ribosome binding to mitochondria.

    DISCUSSION
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Abstract
Introduction
Materials & Methods
Results
Discussion
References

In this report we have demonstrated that ribosomes bind specifically to rat liver mitochondria and that both GTP and the nature of the nascent chain attached to the ribosome affect binding. Specifically, GTP significantly attenuated stable ribosome-mitochondria binding unless mitochondrial transit peptide-containing translation intermediates were complexed with the ribosomes. In addition, a nonhydrolyzable analog of GTP almost completely abolished the formation of stable ribosome-mitochondria complexes whether or not ribosomes carried presequence-containing nascent chains. We also demonstrated that whereas isolated intact mitochondria hydrolyze GTP, hydrolysis of GTP was greatly accelerated when GTPase-depleted ribosomes were added to the reaction.

This report supports, but does not prove, the hypothesis of co-translational mitochondrial import by establishing a central element in this model, namely ribosomes selectively and stably bind to mitochondria. Our data suggest that the interaction of ribosomes with the mitochondria could use components and proceed by a pathway, similar to those used to initiate co-translational translocation at the ER membrane. It is now becoming clear that ribosomes target to the translocation apparatus, specifically, the sec61p complex at the ER membrane independent of the signal recognition particle (SRP) (21, 33). The interaction of the ribosome with both SRP and the translocation apparatus at the ER membrane involves GTP in both complexes (34). At the ER membrane, GTP also controls the release of SRP from SRP receptor and the initiation of delivery of the ribosome-nascent chain complex to the membrane. In short, ribosomes, alone, possess the ability to bind specifically to the ER translocon, but under physiological conditions, G-proteins affect the interactions between components of the targeting apparatus including the SRP-ribosome interaction, the SRP-SRP receptor interaction, and the ribosome-membrane attachment to accomplish correct protein trafficking.

A cytosolic mitochondrial precursor-specific chaperonin, mitochondrial stimulating factor, has been functionally compared with SRP; however, it is an ATP-dependent protein and has only been shown to function post-translationally having no known interaction with the ribosome (13-16). In our experiments, ribosome-mitochondria binding was only modestly affected by ATP, and the ribosome-mitochondria interaction did not have any effect on the rate of ATP hydrolysis. Whether ATP has a direct effect on binding or simply provides a source for generating GTP is unclear. What is clear, however, is that GTPgamma S almost completely disrupted the ribosome-mitochondria binding showing that GTP hydrolysis has an important role in controlling this interaction.

Our results demonstrate that, similar to what occurs at the ER membrane, ribosomes bind tightly to the mitochondrial membrane surface and that at least one GTP-binding factor, and the nature of the nascent chain bound to the ribosome, affect the stability of this interaction. These analogies to protein targeting to the ER have led us to propose that higher eukaryotic mitochondria contain ribosome receptors, possibly similar to the sec61p complex, which are active in initiating co-translational translocation.

We observed that ribosome-mitochondria binding is actively destabilized by GTP unless the ribosome carries a transit peptide-containing nascent chain. That binding is stable in the absence of nucleotide and only mildly disturbed by GDP indicates that ribosomes interact with mitochondria when a G-protein of the binding apparatus is free of nucleotide or loaded with GDP. Since most G-proteins tightly bind GDP, ribosomes probably bind to mitochondria when a G-protein of the binding apparatus is GDP-bound. In general, it is the release of GDP by the action of guanine nucleotide release or exchange protein (GNRP) that allows G-proteins to bind GTP and the action of a third protein, G activation protein, that induces hydrolysis of GTP by G-proteins (35). Because GTPgamma S destabilizes ribosome-mitochondria binding, we know that hydrolysis of GTP is not required to destabilize binding. This implies that it is the action of a GNRP upon ribosome-mitochondria binding that destabilizes the interaction. Since both stimulation of GNRP activity and G activation protein activity result in accelerated GTP hydrolysis, this is consistent with the observation that the rate of GTP hydrolysis by mitochondria increases in the presence of ribosomes. Therefore, we propose that the ribosome-mitochondria interaction stimulates GNRP activity, and that GTP binding to an unidentified G-protein destabilizes binding unless a transit peptide is present. We also suggest that a GNRP is located either on the ribosome, or the mitochondria, and that the G-protein is located on the other so that GTP binding essentially lowers the affinity of the ribosome for the mitochondria. The ribosome-mitochondria interaction behaves similarly to the ribosome-ER interaction except that the action of an SRP-like component that recognizes the transit peptide occurs at the mitochondrial membrane.

These data clearly show a direct link between the cytosolic translation machinery and the mitochondria, as well as a ribosomal influence on mitochondrial GTP hydrolysis. These findings are strongly supportive of the hypothesis that in vivo mitochondrial proteins are imported by co-translational translocation and indicate the potential importance of GTP in the mitochondrial protein import system (7). The current view is that precursor proteins are translated in the cytosol, accompanied by chaperones to the mitochondrial surface, and imported by a specific, multi-subunit import apparatus. However, the experimental observations on which this model is based is biased for several reasons. First, nearly all of the studies defining mitochondrial protein import have used in vitro systems in which the precursor proteins are first translated and then the translated product is added to mitochondria for import. This system works well in defining the import apparatus, but mechanisms for co-translational import are completely missed by this approach. Second, most of the work defining protein import has been accomplished in yeast and Neurospora. However, there are significant differences in transmembrane protein transfer at the ER between yeast and higher eukaryotic cells, showing that yeast is not always representative of more complex cellular processes such as those found in mammalian mitochondria (36). Finally, it is clear that the interior of a eukaryotic cell is highly structured so that even soluble cytoplasmic proteins do not diffuse freely but rather are recruited in specific cytoplasmic domains (37). The current assumption that precursor proteins are translated in the cytosol and then reach their target by chemical diffusion is inconsistent with the current view of a highly structured cytosol and could potentially be rate-limiting for cells with high rates of metabolism. While at least some completely synthesized mitochondrial proteins import post-translationally into isolated mitochondria, the fact that most mitochondrial matrix and inner membrane proteins contain an N-terminal transit peptide suggests that recruiting begins long before protein synthesis is complete.

Further work is necessary to establish the relationship between mitochondria, ribosomes, the nascent polypeptide, and GTP. It is intriguing, however, that other investigators have found G-proteins in the membrane and contact sites of mitochondria of higher eukaryotes (38-40), and it has been recently reported that GTP hydrolysis is required for post-translational protein import into yeast mitochondria (41). Their identity and function remain to be evaluated.

    ACKNOWLEDGEMENTS

We thank Dr. Carroll Cunningham and Dr. Mark O. Lively for critical reading of this manuscript and Dr. Walter G. Jerome for helpful advice in electron microscopy analysis.

    FOOTNOTES

* This work was supported by National Institutes of Health Grants 1F32 GM16826-01 (to K. S. C.) and RO3 AG14223 (to R. M. P.) and a Clinician Scientist Award from the American Heart Association (to R. M. P.).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Dagger To whom correspondence should be addressed: Dept. of Pediatrics, Wake Forest University School of Medicine, Medical Center Blvd., Winston-Salem, NC 27157-1081. Tel.: 910-716-4627; Fax: 910-716-0533; E-mail: mpayne{at}bgsm.edu.

1 The abbreviations used are: ER, endoplasmic reticulum; RER, rough endoplasmic reticulum; GTPgamma S, guanosine-5'-[thio]-triphosphate; EKMT, EDTA, high salt-washed mitochondria; EKMPMT, EDTA/high salt, metrizamide/Percoll-purified mitochondria; mMDH, mitochondrial malate dehydrogenase; SRP, signal recognition particle; GNRP, guanine nucleotide release or exchange protein.

    REFERENCES
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

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