Late-Stage Maturation of the Rieske Fe/S Protein: Mzm1 Stabilizes Rip1 but Does Not Facilitate Its Translocation by the AAA ATPase Bcs1

The final step in the assembly of the ubiquinol-cytochrome c reductase or bc₁ complex involves the insertion of the Rieske Fe/S cluster protein, Rip1. Maturation of Rip1 occurs within the mitochondrial matrix prior to its translocation across the inner membrane (IM) in a process mediated by the Bcs1 ATPase and subsequent insertion into the bc₁ complex. Here we show that the matrix protein Mzm1 functions as a Rip1 chaperone, stabilizing Rip1 prior to the translocation step. In the absence of Mzm1, Rip1 is prone to either proteolytic degradation or temperature-induced aggregation. A series of Rip1 truncations were engineered to probe motifs necessary for Mzm1 interaction and Bcs1-mediated translocation of Rip1. The Mzm1 interaction with Rip1 persists in Rip1 variants lacking its transmembrane domain or containing only its C-terminal globular Fe/S domain. Replacement of the globular domain of Rip1 with that of the heterologous folded protein Grx3 abrogated Mzm1 interaction; however, appending the C-terminal 30 residues of Rip1 to the Rip1-Grx3 chimera restored Mzm1 interaction. The Rip1-Grx3 chimera and a Rip1 truncation containing only the N-terminal 92 residues each induced stabilization of the bc₁:cytochrome oxidase supercomplex in a Bcs1-dependent manner. However, the Rip1 variants were not stably associated with the supercomplex. The induced supercomplex stabilization by the Rip1 N terminus was independent of Mzm1.     

Failure to insert the iron-sulfur cluster into the Rieske iron-sulfur protein impairs both center N and center P of the cytochrome bc1 complex

Mutation of a serine that forms a hydrogen bond to the iron-sulfur cluster of the Rieske iron-sulfur protein to a cysteine results in a respiratory-deficient yeast strain due to formation of iron-sulfur protein lacking the iron-sulfur cluster. The Rieske apoprotein lacking the iron-sulfur cluster is inserted into both monomers of the dimeric cytochrome bc(1) complex and processed to mature size, but the protein lacking iron-sulfur cluster is more susceptible to proteolysis. In addition, the protein environment of center P in one half of the dimer is affected by failure to insert the iron-sulfur cluster as indicated by the fact that only one molecule of myxothiazol can be bound to the cytochrome bc(1) dimer. Although the bc(1) complex lacking the Rieske iron-sulfur cluster cannot oxidize ubiquinol through center P, rates of reduction of cytochrome b by menaquinol through center N are normal. However, less cytochrome b is reduced through center N, and only one molecule of antimycin can be bound at center N in the bc(1) dimer lacking iron-sulfur cluster. These results indicate that failure to insert the [2Fe-2S] cluster impairs assembly of the Rieske protein into the bc(1) complex and that this interferes with proper assembly of both center P and center N in one half of the dimeric enzyme.     

Mne1 is a novel component of the mitochondrial splicing apparatus responsible for processing of a COX1 group I intron in yeast

Saccharomyces cerevisiae cells lacking Mne1 are deficient in intron splicing in the gene encoding the Cox1 subunit of cytochrome oxidase but contain wild-type levels of the bc(1) complex. Thus, Mne1 has no role in splicing of COB introns or expression of the COB gene. Northern experiments suggest that splicing of the COX1 aI5β intron is dependent on Mne1 in addition to the previously known Mrs1, Mss116, Pet54, and Suv3 factors. Processing of the aI5β intron is similarly impaired in mne1Δ and mrs1Δ cells and overexpression of Mrs1 partially restores the respiratory function of mne1Δ cells. Mrs1 is known to function in the initial transesterification reaction of splicing. Mne1 is a mitochondrial matrix protein loosely associated with the inner membrane and is found in a high mass ribonucleoprotein complex specifically associated with the COX1 mRNA even within an intronless strain. Mne1 does not appear to have a secondary function in COX1 processing or translation, because disruption of MNE1 in cells containing intronless mtDNA does not lead to a respiratory growth defect. Thus, the primary defect in mne1Δ cells is splicing of the aI5β intron in COX1.     

Bcs1, a AAA protein of the mitochondria with a role in the biogenesis of the respiratory chain

The family of AAA+ proteins in eukaryotes has many members in various cellular compartments with a broad spectrum of functions in protein unfolding and degradation. The mitochondrial AAA protein Bcs1 plays an unusual role in protein translocation. It is involved in the topogenesis of the Rieske protein, Rip1, and thereby in the biogenesis of the cytochrome bc(1) complex of the mitochondrial respiratory chain. Bcs1 mediates the export of the folded FeS domain of Rip1 across the mitochondrial inner membrane and the insertion of its transmembrane segment into an assembly intermediate of the cytochrome bc(1) complex. We discuss structural elements of the Bcs1 protein compared to other AAA proteins in an attempt to understand the mechanism of its function. In this context, we discuss human diseases caused by mutations in Bcs1 that lead to different properties of the protein and subsequently to different symptoms.     

Elimination of the disulfide bridge in the Rieske iron-sulfur protein allows assembly of the [2Fe-2S] cluster into the Rieske protein but damages the ubiquinol oxidation site in the cytochrome bc1 complex

The [2Fe-2S] cluster of the Rieske iron-sulfur protein is held between two loops of the protein that are connected by a disulfide bridge. We have replaced the two cysteines that form the disulfide bridge in the Rieske protein of Saccharomyces cerevisiae with tyrosine and leucine, and tyrosine and valine, to evaluate the effects of the disulfide bridge on assembly, stability, and thermodynamic properties of the Rieske iron-sulfur cluster. EPR spectra of the Rieske proteins lacking the disulfide bridge indicate the iron-sulfur cluster is assembled in the absence of the disulfide bridge, but there are significant shifts in all g values, indicating a change in the electronic structure of the [2Fe-2S] iron-sulfur center. In addition, the midpoint potential of the iron-sulfur cluster is lowered from 265 mV in the Rieske protein from wild-type yeast to 150 mV in the protein from the C164Y/C180L mutant and to 160 mV in the protein from the C164Y/C180V mutant. Ubiquinol-cytochrome c reductase activities of the bc(1) complexes with Rieske proteins lacking the disulfide bridge are less than 1% of the activity of the bc(1) complex from wild-type yeast, even though normal amounts of the iron-sulfur protein are present as judged by Western blot analysis. These activities are lower than the 105-115 mV decrease in the midpoint potential of the Rieske iron-sulfur cluster can account for. Pre-steady-state reduction of the bc(1) complexes with menadiol indicates that quinol is not oxidized through center P but is oxidized through center N. In addition, the levels of stigmatellin and UHDBT binding are markedly diminished, while antimycin binding is unaffected, in the bc(1) complexes with Rieske proteins lacking the disulfide bridge. Taken together, these results indicate that the ubiquinol oxidation site at center P is damaged in the bc(1) complexes with Rieske proteins lacking the disulfide bridge even though the iron-sulfur cluster is assembled into the Rieske protein.     

A pathway of protein translocation in mitochondria mediated by the AAA-ATPase Bcs1

The AAA+ family in eukaryotes has many members in various cellular compartments with a role in protein unfolding and degradation. We show that the mitochondrial AAA-ATPase Bcs1 has an unusual function in protein translocation. Bcs1 mediates topogenesis of the Rieske protein, Rip1, a component of respiratory chains in bacteria, mitochondria, and chloroplasts. The oligomeric AAA-ATPase Bcs1 is involved in export of the folded Fe-S domain of Rip1 across the inner membrane and insertion of its transmembrane segment into an assembly intermediate of the cytochrome bc(1) complex, thus revealing an unexpected mechanistical concept of protein translocation across membranes. Furthermore, we describe structural elements of Rip1 required for recognition and export by as well as ATP-dependent lateral release from the AAA-ATPase. In bacteria and chloroplasts Rip1 uses the Tat machinery for topogenesis; however, mitochondria have lost this machinery during evolution and a member of the AAA-ATPase family has taken over its function.     

Assembly of the iron-sulfur protein into the cytochrome b-c1, complex of yeast mitochondria.

The assembly of the iron-sulfur protein into the cytochrome bc1 complex after import and processing of the precursor form into mitochondria in vitro was investigated by immunoprecipitation of the radiolabeled iron-sulfur protein from detergent-solubilized mitochondria with specific antisera. After import in vitro, the labeled mature form of the iron-sulfur protein was immunoprecipitated by antisera against both the iron-sulfur protein and the entire bc1 complex from mitochondria solubilized with either Triton X-100 or dodecyl maltoside. After sodium dodecyl sulfate solubilization of mitochondria, however, the antiserum against the iron-sulfur protein, but not that against the bc1 complex, immunoprecipitated the radiolabeled iron-sulfur protein. These results suggest that in mitochondria the mature form of the iron-sulfur protein is assembled with other subunits of the bc1 complex that are recognized by the antiserum against the bc1 complex. By contrast, the intermediate and precursor forms of the iron-sulfur protein that accumulated in the matrix when proteolytic processing was blocked with EDTA and o-phenanthroline were not efficiently assembled into the bc1 complex. The import and processing of the iron-sulfur protein also occurred in mitochondria lacking either cytochrome b (W-267) or the iron-sulfur protein (JPJ1). The mature form of the iron-sulfur protein was immunoprecipitated by antisera against the bc1 complex or core protein I after import in vitro into these mitochondria, suggesting that the mature form is associated with other subunits of the bc1 complex in these strains.     

The iron-sulfur protein is necessary for the complete assembly of the low-molecular-weight subunits into the cytochrome b-c1 complex of yeast mitochondria

A strain of yeast lacking the gene for the Rieske iron-sulfur protein (RIP) of the cytochrome b-c1 complex was used to study the assembly of this complex in the mitochondrial membrane. This strain lacks the mRNA for the iron-sulfur protein as evidenced by both Northern hybridization using a probe containing the coding region of the gene plus in vitro translation of total RNA followed by immunoprecipitation with a specific antibody against the iron-sulfur protein. In addition, isolated mitochondria from this strain lacked cytochrome c reductase activity with either succinate or the decyl analog of ubiquinol as substrate. Immunoblotting studies with antiserum against the cytochrome b-c1 complex revealed that mitochondria from the iron-sulfur protein-deficient strain have levels of core protein I, core protein II, and cytochrome c1 equal to those of wild-type mitochondria; however, a decrease in cytochrome b was evident from both immunoblotting and spectral analysis. Moreover, it is evident from the immunoprecipitates of radiolabeled mitochondria that the amounts of the low-molecular-weight subunits (17, 14, and 11 kDa) are decreased 53, 65, and 50%, respectively, in mitochondria lacking the iron-sulfur protein. These results suggest that the iron-sulfur protein is required for the complete assembly of the low-molecular-weight subunits into the cytochrome b-c1 complex.     

The iron-sulfur protein of cytochrome bc1 complex. Its occurrence in the mitochondrial inner membrane in excess of the amount constituting the complex

Radioimmunoassay and quantitative immunoblot analysis have been developed for quantitation of the iron-sulfur protein of cytochrome bc1 complex in order to compare its content in isolated cytochrome bc1 complex with that in electron transport particles. The result by radioimmunoassay indicated that the content of the iron-sulfur protein/mol of cytochrome b is higher by approximately 30%, on the average, in electron transport particles than in cytochrome bc1 complex. This observation was supported by the data of immunoblot analysis. Since approximately 1/3 of cytochrome b in electron transport particles is not attributed to cytochrome bc1 complex, but to succinate-ubiquinone oxidoreductase complex (Davis, K.A., Hatefi, Y., Poff, K. L., and Butler, W. L. (1973) Biochim. Biophys. Acta 325, 341-356), the ratio of the iron-sulfur protein detectable by radioimmunoassay in electron transport particles to that in cytochrome bc1 complex is calculated to be approximately 2 on the basis of the content of 2 mol of b-type heme/mol of the complex. Therefore, it appears that the mitochondrial inner membrane contains approximately two times as much of the immunoreactive iron-sulfur protein as what is expected from the stoichiometry of one iron-sulfur center and two b-type hemes for cytochrome bc1 complex. This finding affords an interesting aspect in the study of biogenesis of cytochrome bc1 complex.     

The iron-sulfur cluster of the Rieske iron-sulfur protein functions as a proton-exiting gate in the cytochrome bc(1) complex

The destruction of the Rieske iron-sulfur cluster ([2Fe-2S]) in the bc(1) complex by hematoporphyrin-promoted photoinactivation resulted in the complex becoming proton-permeable. To study further the role of this [2Fe-2S] cluster in proton translocation of the bc(1) complex, Rhodobacter sphaeroides mutants expressing His-tagged cytochrome bc(1) complexes with mutations at the histidine ligands of the [2Fe-2S] cluster were generated and characterized. These mutants lacked the [2Fe-2S] cluster and possessed no bc(1) activity. When the mutant complex was co-inlaid in phospholipid vesicles with intact bovine mitochondrial bc(1) complex or cytochrome c oxidase, the proton ejection, normally observed in intact reductase or oxidase vesicles during the oxidation of their corresponding substrates, disappeared. This indicated the creation of a proton-leaking channel in the mutant complex, whose [2Fe-2S] cluster was lacking. Insertion of the bc(1) complex lacking the head domain of the Rieske iron-sulfur protein, removed by thermolysin digestion, into PL vesicles together with mitochondrial bc(1) complex also rendered the vesicles proton-permeable. Addition of the excess purified head domain of the Rieske iron-sulfur protein partially restored the proton-pumping activity. These results indicated that elimination of the [2Fe-2S] cluster in mutant bc(1) complexes opened up an otherwise closed proton channel within the bc(1) complex. It was speculated that in the normal catalytic cycle of the bc(1) complex, the [2Fe-2S] cluster may function as a proton-exiting gate.     

Cytochrome b is necessary for the effective processing of core protein I and the iron-sulfur protein of complex III in the mitochondria

The effect of cytochrome b on the assembly of the subunits of complex III into the inner mitochondrial membrane has been studied in a mutant of yeast (W-267, Box 6-2) that lacks a spectrally detectable cytochrome b and synthesizes a shortened form of apocytochrome b. We recently reported that several cytochrome b-deficient mutants contained significantly diminished amounts of core proteins I and II as well as the iron-sulfur protein, but contained equal amounts of cytochrome c1 compared to the wild type (K. Sen and D. S. Beattie, Arch. Biochem. Biophys. 242, 393-401, 1985). In the present study, the time course of processing of precursors of both core protein I and the iron-sulfur protein which had accumulated in cells treated with the uncoupler carbonyl m-chlorophenyl hydrazone (CCCP) was noted to be significantly lower in the mutant compared to the wild type. The amounts of the mature forms of these proteins in mitochondria pulse labeled under different conditions was also considerably decreased at all times studied. The synthesis of both proteins appeared to be unaffected in the mutant, as the precursor forms of both proteins accumulated to the same extent when processing in vivo was blocked by CCCP. Furthermore, translation of RNA in a reticulocyte lysate in vitro indicated that the messenger RNAs for both proteins were present in the mutant and translated with equal efficiency. The import into isolated mitochondria of the precursor forms of the iron-sulfur protein synthesized in the cell-free system was also decreased in the mutant mitochondria. In addition, the precursor form was bound to the exterior of the mitochondrial membrane where it was sensitive to digestion with proteases. By contrast, the synthesis and processing of cytochrome c1 appeared to be unaffected in these mutants. These results suggest that cytochrome b is necessary for the proper processing and assembly of both core protein I and the iron-sulfur protein, but not for cytochrome c1, into complex III of the inner mitochondrial membrane.     

A compensatory double mutation of the alanine-86 to leucine mutant located in the hinge region of the iron-sulfur protein of the yeast cytochrome bc1 complex

Mutations in the hinge region connecting the membrane anchor to the extra-membranous head-group of the iron-sulfur protein can impede proper assembly and function of the cytochrome bc(1) complex. Mutating the conserved alanines, residues 86, 90, and 92, located in the hinge region resulted in a 30-50% decrease in enzymatic activity without loss of the iron-sulfur protein [J. Bioenerg. Biomembr. 31 (1999) 215]. The lowered enzymatic activity in the A86L mutant was shown to result from steric interference between the side chains of Leu-86 and Leu-89 [Biochemistry 40 (2001) 327]. The compensatory double mutant A86L/L89A restored activity to wild type levels and relieved the steric hindrance; however, the L89A mutant did not assemble properly into the bc(1) complex. Molecular modeling studies of these mutants compared to the wild type have suggested that the hydrophobic residues located in the hinge region are critical to the motion of the head group of the iron-sulfur protein during catalysis.     

Mutations in the tether region of the iron-sulfur protein affect the activity and assembly of the cytochrome bc(1) complex of yeast mitochondria

Resolution of the crystal structure of the mitochondrial cytochrome bc(1) complex has indicated that the extra-membranous extrinsic domain of the iron-sulfur protein containing the 2Fe2S cluster is connected by a tether to the transmembrane helix that anchors the iron-sulfur protein to the complex. To investigate the role of this tether in the cytochrome bc(1) complex, we have mutated the conserved amino acid residues Ala-86, Ala-90, Ala-92, Lys-93 and Glu-95 and constructed deletion mutants DeltaVLA(88-90) and DeltaAMA(90-92) and an insertion mutant I87AAA88 in the iron-sulfur protein of the yeast, Saccharomyces cerevisiae. In cells grown at 30 degrees C, enzymatic activities of the bc(1) complex were reduced 22-56% in mutants A86L, A90I, A92C, A92R and E95R, and the deletion mutants, DeltaVLA(88-90) and DeltaAMA(90-92), while activity of the insertion mutant was reduced 90%. No loss of cytochromes b or c-c(1), detected spectrally, or the iron-sulfur protein, determined by quantitative immunoblotting, was observed in these mutants with the exception of the mutants of Ala-92 in which the loss of activity paralleled a loss in the amount of the iron-sulfur protein. EPR spectroscopy revealed no changes in the iron-sulfur cluster of mutants A86L, A90I, A92R or the deletion mutant DeltaVLA(88-90). Greater losses of both protein and activity were observed in all of the mutants of Ala-92 as well as in A90F grown at 37 degrees C. suggesting that these conserved alanine residues may be involved in maintaining the stability of the iron-sulfur protein and its assembly into the bc(1) complex. By contrast, no significant loss of iron-sulfur protein was observed in the mutants of Ala-86 in cells grown at either 30 degrees C or 37 degrees C despite the 50-70% loss of enzymatic activity suggesting that Ala-86 may play a critical role in catalysis in the bc(1) complex.     

Intermediate length Rieske iron-sulfur protein is present and functionally active in the cytochrome bc1 complex of Saccharomyces cerevisiae

To investigate the relationship between post-translational processing of the Rieske iron-sulfur protein of Saccharomyces cerevisiae and its assembly into the mitochondrial cytochrome bc1 complex we used iron-sulfur proteins in which the presequences had been changed by site-directed mutagenesis of the cloned iron-sulfur protein gene, so that the recognition sites for the matrix processing peptidase or the mitochondrial intermediate peptidase (MIP) had been destroyed. When yeast strain JPJ1, in which the gene for the iron-sulfur protein is deleted, was transformed with these constructs on a single copy expression vector, mitochondrial membranes and bc1 complexes isolated from these strains accumulated intermediate length iron-sulfur proteins in vivo. The cytochrome bc1 complex activities of these membranes and bc1 complexes indicate that intermediate iron-sulfur protein (i-ISP) has full activity when compared with that of mature sized iron-sulfur protein (m-ISP). Therefore the iron-sulfur cluster must have been inserted before processing of i-ISP to m-ISP by MIP. When iron-sulfur protein is imported into mitochondria in vitro, i-ISP interacts with components of the bc1 complex before it is processed to m-ISP. These results establish that the iron-sulfur cluster is inserted into the apoprotein before MIP cleaves off the second part of the presequence and that this second processing step takes place after i-ISP has been assembled into the bc1 complex.     

Direct interaction between the internal NADH: ubiquinone oxidoreductase and ubiquinol:cytochrome c oxidoreductase in the reduction of exogenous quinones by yeast mitochondria.

The reduction of duroquinone (DQ) and 2,3-dimethoxy-5-methyl-6-decyl-1,4-benzoquinone (DB) by NADH and ethanol was investigated in intact yeast mitochondria with good respiratory control ratios. In these mitochondria, exogenous NADH is oxidized by the NADH dehydrogenase localized on the outer surface of the inner membrane, whereas the NADH produced by ethanol oxidation in the mitochondrial matrix is oxidized by the NADH dehydrogenase localized on the inner surface of the inner membrane. The reduction of DQ by ethanol was inhibited 86% by myxothiazol; however, the reduction of DQ by NADH was inhibited 18% by myxothiazol, suggesting that protein-protein interactions between the internal (but not the external) NADH: ubiquinone oxidoreductase and ubiquinol:cytochrome c oxidoreductase (the cytochrome bc1 complex) are involved in the reduction of DQ by NADH. The reduction of DQ and DB by NADH and ethanol was also investigated in mutants of yeast lacking cytochrome b, the iron-sulfur protein, and ubiquinone. The reduction of both quinone analogues by exogenous NADH was reduced to levels that were 10 to 20% of those observed in wild-type mitochondria; however, the rate of their reduction by ethanol in the mutants was equal to or greater than that observed in the wild-type mitochondria. Furthermore, the reduction of DQ in the cytochrome b and iron-sulfur protein lacking mitochondria was myxothiazol sensitive, suggesting that neither of these proteins is an essential binding site for myxothiazol. The mitochondria from the three mutants also contained significant amounts of antimycin- and myxothiazol-insensitive NADH:cytochrome c reductase activity, but had no detectable succinate:cytochrome c reductase activity. These results suggest that the mutants lacking a functional cytochrome bc1 complex have adapted to oxidize NADH.     

Thyroid hormone regulation of nuclear-encoded mitochondrial inner membrane polypeptides of the liver

The effects of thyroid hormone on nuclear-encoded mitochondrial inner membrane proteins were investigated by in vitro translation of the endogenous mRNA present in a postmitochondrial fraction from the livers of rats treated in vivo with hormone. The levels of the mRNAs were estimated by quantitative immunoabsorption of the translation mixture. Total protein synthesis was increased 2.6-fold after 4 days of in vivo hormone treatment, but only 10-15% of the polypeptides were dramatically altered (greater than 5-fold). Among the most highly elevated were cytochrome c1 (greater than 10-fold increase) and the Rieske iron-sulfur protein of the cytochrome bc1 complex. Other inner membrane proteins (core protein 1, beta subunit of F1 ATPase, subunit IV of cytochrome oxidase, 3-hydroxybutyrate dehydrogenase) and non-mitochondrial proteins (rat serum albumin, beta 2-microglobulin) were not altered significantly by hormone treatment. Cytochrome c1 and the Rieske protein increased after 12 h of hormone treatment, a relatively early response in mammalian mitochondrial biogenesis. The possible significance of this response for the regulation of mitochondrial synthesis and assembly is discussed.     

Bub1, Sgo1, and Mps1 mediate a distinct pathway for chromosome biorientation in budding yeast

The conserved mitotic kinase Bub1 performs multiple functions that are only partially characterized. Besides its role in the spindle assembly checkpoint and chromosome alignment, Bub1 is crucial for the kinetochore recruitment of multiple proteins, among them Sgo1. Both Bub1 and Sgo1 are dispensable for growth of haploid and diploid budding yeast, but they become essential in cells with higher ploidy. We find that overexpression of SGO1 partially corrects the chromosome segregation defect of bub1Δ haploid cells and restores viability to bub1Δ tetraploid cells. Using an unbiased high-copy suppressor screen, we identified two members of the chromosomal passenger complex (CPC), BIR1 (survivin) and SLI15 (INCENP, inner centromere protein), as suppressors of the growth defect of both bub1Δ and sgo1Δ tetraploids, suggesting that these mutants die due to defects in chromosome biorientation. Overexpression of BIR1 or SLI15 also complements the benomyl sensitivity of haploid bub1Δ and sgo1Δ cells. Mutants lacking SGO1 fail to biorient sister chromatids attached to the same spindle pole (syntelic attachment) after nocodazole treatment. Moreover, the sgo1Δ cells accumulate syntelic attachments in unperturbed mitoses, a defect that is partially corrected by BIR1 or SLI15 overexpression. We show that in budding yeast neither Bub1 nor Sgo1 is required for CPC localization or affects Aurora B activity. Instead we identify Sgo1 as a possible partner of Mps1, a mitotic kinase suggested to have an Aurora B-independent function in establishment of biorientation. We found that Sgo1 overexpression rescues defects caused by metaphase inactivation of Mps1 and that Mps1 is required for Sgo1 localization to the kinetochore. We propose that Bub1, Sgo1, and Mps1 facilitate chromosome biorientation independently of the Aurora B-mediated pathway at the budding yeast kinetochore and that both pathways are required for the efficient turnover of syntelic attachments.     

Processing of the intermediate form of the iron-sulfur protein of the BC1 complex to the mature form after import into yeast mitochondria.

The Rieske iron-sulfur protein of the cytochrome bc1 complex is synthesized in the cytosol as a precursor with an additional 30 amino acids at the amino terminus. After import into the mitochondrial matrix, the precursor is processed to the mature form by two distinct proteolytic cleavages. Addition of 2.5 mM EDTA and 0.5 mM o-phenanthroline to the incubation mixture during import of the iron-sulfur protein precursor in vitro resulted in the selective inhibition of the second processing step with the concomitant accumulation of the intermediate form. The intermediate form was chased to the mature form in the presence of antimycin and oligomycin (to block the formation of a membrane potential) provided that 0.5 nM ATP and a metal ion such as Ca2+, Mn2+, or Mg2+ were added. Ca2+ ion was the most effective and at a concentration of 2.5 mM resulted in the complete cleavage of the intermediate to the mature form. Addition of Zn2+, Co2+, Mo2+, and Fe2+ was not effective in restoring the second cleavage. The pH optimum for the processing of the intermediate form of the iron-sulfur protein to the mature form was between 6.8-8.0. Processing of the intermediate form of the iron-sulfur protein to the mature form was observed at temperatures ranging from 12 to 27 degrees C in a temperature-dependent manner. The time course during the chase indicated that the second processing step was completed within 2 min after addition of Ca2+ ions. Attempts to isolate the second processing enzyme by sonication of mitochondria or by solubilization with detergents such as digitonin, Triton X-100, dodecyl-maltoside, or octyl-glucoside were unsuccessful as only the first cleavage was observed. Hence, the second processing enzyme may be present in the inner membrane or matrix in a conformation disrupted by detergents or alternatively the enzyme may be very labile.     

The extra fragment of the iron-sulfur protein (residues 96-107) of Rhodobacter sphaeroides cytochrome bc1 complex is required for protein stability

Sequence alignment of the Rieske iron-sulfur protein (ISP) of cytochrome bc(1) complex from various sources reveals that bacterial ISPs contain an extra fragment. To study the role of this fragment in bacterial cytochrome bc(1) complex, Rhodobacter sphaeroides mutants expressing His-tagged cytochrome bc(1) complexes with deletion or single- or multiple-alanine substitution at various positions of this fragment (residues 96-107) were generated and characterized. The ISPDelta(96-107), ISP(96-107)A, and ISP(104-107)A mutant cells, in which residues 96-107 of ISP are deleted, and residues 96-107 and 104-107 are substituted with alanine, respectively, do not grow photosynthetically and show no bc(1) complex activity in intracytoplasmic membranes prepared from these mutant cells. The ISP(96-99)A, in which residues 96-99 are substituted with alanine, grows photosynthetically at a rate comparable to that of the complement cells, whereas ISP(100-103)A, in which residues 100-103 are substituted with alanine, has a longer lag period prior to photosynthetic growth. Chromatophores prepared from these two mutant cells have 48% and 9% of the bc(1) activity found in the complement chromatophores. The loss (or decrease) of bc(1) activity in these mutant membranes results from a lack (or decrease) of ISP in the membrane due to ISP protein instability and not from mutations affecting the assembly of cytochromes b and c(1) into the membrane, the binding affinity of cytochrome b to cytochrome c(1), or the ability of these two cytochromes to interact with ISP or subunit IV. The order of essentiality of residues in this fragment is residues 104-107 > residues 100-103 > residues 96-99.