Mutational analysis of assembly and function of the iron-sulfur protein of the cytochrome bc1 complex in Saccharomyces cerevisiae

A concerted ATPase cycle of the protein transporter AAA-ATPase Bcs1

Bcs1, a homo-heptameric transmembrane AAA-ATPase, facilitates folded Rieske iron-sulfur protein translocation across the inner mitochondrial membrane. Structures in different nucleotide states (ATPγS, ADP, apo) provided conformational snapshots, but the kinetics and structural transitions of the ATPase cycle remain elusive. Here, using high-speed atomic force microscopy (HS-AFM) and line scanning (HS-AFM-LS), we characterized single-molecule Bcs1 ATPase cycling. While the ATP conformation had ~5600 ms lifetime, independent of the ATP-concentration, the ADP/apo conformation lifetime was ATP-concentration dependent and reached ~320 ms at saturating ATP-concentration, giving a maximum turnover rate of 0.17 s-1. Importantly, Bcs1 ATPase cycle conformational changes occurred in concert. Furthermore, we propose that the transport mechanism involves opening the IMS gate through energetically costly straightening of the transmembrane helices, potentially driving rapid gate resealing. Overall, our results establish a concerted ATPase cycle mechanism in Bcs1, distinct from other AAA-ATPases that use a hand-over-hand mechanism.

Structural snapshots of the cellular folded protein translocation machinery Bcs1

Proteins destined to various intra‐ and extra‐cellular locations must traverse membranes most frequently in an unfolded form. When the proteins being translocated need to remain in a folded state, specialized cellular transport machinery is used. One such machine is the membrane‐bound AAA protein Bcs1 (Bcs1), which assists the iron‐sulfur protein, an essential subunit of the respiratory Complex III, across the mitochondrial inner membrane. Recent structure determinations of mouse and yeast Bcs1 in three different nucleotide states reveal its homo‐heptameric association and at least two dramatically different conformations. The apo and ADP‐bound structures are similar, both containing a large substrate‐binding cavity accessible to the mitochondrial matrix space, which contracts by concerted motion of the ATPase domains upon ATP binding, suggesting that bound substrate could then be pushed across the membrane. ATP hydrolysis drives substrate release and resets Bcs1 conformation back to the apo/ADP form. These structures shed new light on the mechanism of folded protein translocation across a membrane, provide better understanding on the assembly process of the respiratory Complex III, and correlate clinical presentations of disease‐associated mutations with their locations in the 3D structure.

Structures of AAA protein translocase Bcs1 suggest translocation mechanism of a folded protein

The mitochondrial membrane-bound AAA protein Bcs1 translocate substrates across the mitochondrial inner membrane without previous unfolding. One substrate of Bcs1 is the iron-sulfur protein (ISP), a subunit of the respiratory Complex III. How Bcs1 translocates ISP across the membrane is unknown. Here we report structures of mouse Bcs1 in two different conformations, representing three nucleotide states. The apo and ADP-bound structures reveal a homo-heptamer and show a large putative substrate-binding cavity accessible to the matrix space. ATP binding drives a contraction of the cavity by concerted motion of the ATPase domains, which could push substrate across the membrane. Our findings shed light on the potential mechanism of translocating folded proteins across a membrane, offer insights into the assembly process of Complex III and allow mapping of human disease-associated mutations onto the Bcs1 structure.

Identification and characterization of the major mitochondrial Fe transporter in rice

The uptake, translocation, and compartmentalization of Fe are essential for plant cell function and life cycle. Despite rapid progress in our understanding of Fe homeostasis in plants, Fe transport from the cytoplasm to mitochondria was, until recently, poorly understood. The screening of 3,993 mutant lines for symptoms of Fe deficiency resulted in the identification and characterization of a major mitochondrial Fe transporter (MIT) in rice. MIT was found to localize to mitochondria and to complement the growth of a yeast strain defective in mitochondrial Fe transport. The knock-out of MIT resulted in a lethal phenotype, and in knock-down plants, several agronomic characteristics were compromised, such as plant height, average number of tillers, days to flower, fertility, and yield. Changes in the expression of genes involved in Fe transport suggested a disturbance of cellular Fe transport. Furthermore, the mitochondrial Fe concentration and the activity of the mitochondrial Fe-S enzyme aconitase were significantly reduced compared with wild-type plants. The identification of MIT is a significant advance in the field of plant Fe nutrition and should facilitate the cloning of paralogs from other plant species. 

The rice mitochondrial iron transporter is essential for plant growth

In plants, iron (Fe) is essential for mitochondrial electron transport, heme, and Fe-Sulphur (Fe-S) cluster synthesis; however, plant mitochondrial Fe transporters have not been identified. Here we show, identify and characterize the rice mitochondrial Fe transporter (MIT). Based on a transfer DNA library screen, we identified a rice line showing symptoms of Fe deficiency while accumulating high shoot levels of Fe. Homozygous knockout of MIT in this line resulted in a lethal phenotype. MIT localized to the mitochondria and complemented the growth of Δmrs3Δmrs4 yeast defective in mitochondrial Fe transport. The growth of MIT-knockdown (mit-2) plants was also significantly impaired despite abundant Fe accumulation. Further, the decrease in the activity of the mitochondrial and cytosolic Fe-S enzyme, aconitase, indicated that Fe-S cluster synthesis is affected in mit-2 plants. These results indicate that MIT is a mitochondrial Fe transporter essential for rice growth and development.

Increasing the nutritional content of plant crops and the identification of iron transporters in rice would facilitate the improvement of rice varieties. In this study, the authors identify a mitochondrial iron transporter in rice — MIT — and suggest that this gene is important for rice growth and development.

The Rieske Iron-Sulfur Protein: Import and Assembly into the Cytochrome bc(1) Complex of Yeast Mitochondria

The Rieske iron-sulfur protein, one of the catalytic subunits of the cytochrome bc₁ complex, is involved in electron transfer at the level of the inner membrane of yeast mitochondria. The Rieske iron-sulfur protein is encoded by nuclear DNA and, after being synthesized in the cytosol, is imported into mitochondria with the help of a cleavable N-terminal presequence. The imported protein, besides incorporating the 2Fe-2S cluster, also interacts with other catalytic and non-catalytic subunits of the cytochrome bc₁ complex, thereby assembling into the mature and functional respiratory complex. In this paper, we summarize the most recent findings on the import and assembly of the Rieske iron-sulfur protein into Saccharomyces cerevisiae mitochondria, also discussing a possible role of this protein both in the dimerization of the cytochrome bc₁ complex and in the interaction of this homodimer with other complexes of the mitochondrial respiratory chain.

Engineering of protease variants exhibiting high catalytic activity and exquisite substrate selectivity

The exquisite selectivity and catalytic activity of enzymes have been shaped by the effects of positive and negative selection pressure during the course of evolution. In contrast, enzyme variants engineered by using in vitro screening techniques to accept novel substrates typically display a higher degree of catalytic promiscuity and lower total turnover in comparison with their natural counterparts. Using bacterial display and multiparameter flow cytometry, we have developed a novel methodology for emulating positive and negative selective pressure in vitro for the isolation of enzyme variants with reactivity for desired novel substrates, while simultaneously excluding those with reactivity toward undesired substrates. Screening of a large library of random mutants of the Escherichia coli endopeptidase OmpT led to the isolation of an enzyme variant, 1.3.19, that cleaved an Ala-Arg peptide bond instead of the Arg-Arg bond preferred by the WT enzyme. Variant 1.3.19 exhibited greater than three million-fold selectivity (-Ala-Arg-/-Arg-Arg-) and a catalytic efficiency for Ala-Arg cleavage that is the same as that displayed by the parent for the preferred substrate, Arg-Arg. A single amino acid Ser223Arg substitution was shown to recapitulate completely the unique catalytic properties of the 1.3.19 variant. These results can be explained by proposing that this mutation acts to "swap" the P(1) Arg side chain normally found in WT substrate peptides with the 223Arg side chain in the S(1) subsite of OmpT.

Aspartate-186 in the head group of the yeast iron–sulfur protein of the cytochrome bc1 complex contributes to the protein conformation required for efficient electron transfer

Two conserved charged amino acids, aspartate-186 and arginine-190, localized in the aqueous head region of the iron-sulfur protein of the cytochrome bc(1) complex of yeast mitochondria, were mutated to alanine, glutamate, or asparagine and isoleucine, respectively. The R190I mutation resulted in the complete loss of antimycin- and myxothiazol-sensitive cytochrome c reductase activity due to loss of more than 60% of the iron-sulfur protein in the complex. Mitochondria isolated from the D186A mutant had a 50% decrease in cytochrome c reductase activity but no loss of the iron-sulfur protein or the [2Fe-2S] cluster. The midpoint potential of the [2Fe-2S] cluster of the D186A mutant was decreased from 281 to 178 mV. The D186E and D186N mutations did not result in a loss of cytochrome c reductase activity or content of iron-sulfur protein; however, the redox potential of the [2Fe-2S] cluster of D186N was decreased from 281 to 241 mV. Molecular modeling/dynamics studies predicted that substituting an alanine for Asp-186 causes global structural changes in the head group of the iron-sulfur protein resulting in changes in the orientation of the [2Fe-2S] cluster and consequently a lowered redox potential. The rate of electrogenic proton pumping in the bc(1) complex isolated from mutant D186A reconstituted into proteoliposomes decreased 64%; however, the H(+)/2e(-) ratio of 1.9 was identical in the mutant and the wild-type complexes. The carboxyl binding reagent, N-(ethoxycarbonyl)-2-ethoxyl-1,2-dihydroquinoline (EEDQ) blocked electrogenic proton pumping in the bc(1) complex reconstituted into proteoliposomes without affecting electron transfer resulting in a decrease in the H(+)/2e(-) ratio to 1.2 and 1.1, respectively. EEDQ was bound to the iron-sulfur protein and core protein II in both the wild type and the D186A mutant, indicating that Asp-186 of the iron-sulfur protein is not required for proton translocation in the bc(1) complex.

Mitochondrial processing peptidases

Three peptidases are responsible for the proteolytic processing of both nuclearly and mitochondrially encoded precursor polypeptides targeted to the various subcompartments of the mitochondria. Mitochondrial processing peptidase (MPP) cleaves the vast majority of mitochondrial proteins, while inner membrane peptidase (IMP) and mitochondrial intermediate peptidase (MIP) process specific subsets of precursor polypeptides. All three enzymes are structurally and functionally conserved across species, and their human homologues begin to be recognized as potential players in mitochondrial disease.

Ischemic injury to mitochondrial electron transport in the aging heart: damage to the iron-sulfur protein subunit of electron transport complex III

The aging heart sustains greater injury during ischemia and reperfusion compared to adult hearts. Aging decreases oxidative function in interfibrillar mitochondria (IFM) that reside among the myofibers, while subsarcolemmal mitochondria (SSM), located beneath the plasma membrane, remain unaltered. Aging decreases complex III activity selectively in IFM via alteration of the cytochrome c binding site. With 25 min of global ischemia, complex III activity decreases in SSM and further decreases in IFM in the aging heart. Ischemia leads to a marked decrease in the electron paramagnetic resonance signal of the iron-sulfur protein (ISP) in both SSM and IFM, despite a preserved content of ISP peptide. Thus, ischemia results in a functional decrease in the iron-sulfur center in ISP without subunit peptide loss. In the aging heart, at the onset of reperfusion, IFM contain two tandem defects in the path of electron flow through complex III, providing a likely mechanism for enhanced oxidant production and reperfusion damage.

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.

Assembly of the Rieske iron-sulphur protein into the cytochrome bf complex in thylakoid membranes of isolated pea chloroplasts

The assembly of the Rieske iron-sulphur protein into the cytochrome bf complex was examined following import of 35S-labeled precursor protein by isolated pea chloroplasts. Rieske protein assembled into the cytochrome bf complex was resolved from unassembled Rieske protein and from other membrane complexes by nondenaturing gel electrophoresis of dodecyl maltoside-solubilized thylakoid membranes. Four mutant forms of the Rieske protein were able to assemble into the cytochrome bf complex in isolated chloroplasts. These were a triple substitution mutant, C107S/H109R/C112S, replacing conserved residues involved in the ligation of the [2Fe-2S] centre; the mutant Delta45-52 which removed a glycine-rich region predicted to form a flexible hinge between the hydrophobic membrane-associated region and the hydrophilic lumenal domain; and mutants Delta168-173 and Delta177-179 which removed two C-terminal regions, which are highly conserved in chloroplast and cyanobacterial Rieske proteins. This indicates that the [2Fe-2S] cluster, the glycine-rich region and the C-terminal region are not essential for stable assembly of the Rieske protein into the cytochrome bf complex in isolated chloroplasts.

Electrochemical and spectroscopic investigations of the cytochrome bc1 complex from Rhodobacter capsulatus

The cytochrome bc(1) complex from Rhodobacter capsulatus was investigated by protein electrochemistry and visible/IR spectroscopy. Infrared difference spectra, which represent redox-induced conformational changes of cofactors and their protein environments, show signals of the hemes, the quinone Q(i), and small conformational changes of the protein backbone. Furthermore, band features were tentatively assigned to protonated aspartic or glutamic acids involved in the redox transition of each of the b hemes, a proline in that of the [2Fe-2S] protein, and an arginine in that of cytochrome b(H). The midpoint potential of the [2Fe-2S] protein was determined for the first time at physiological temperature to be +290 mV at pH 8.7. The reduced minus oxidized difference extinction coefficients of the alpha-bands of the cytochromes were calculated as 11.5, 19, and 6.7 mM(-1) cm(-1) for cytochromes c(1), b(H), and b(L), respectively. A novel method has been developed to quantify protonation reactions of the complex during the redox reactions of its cofactors by evaluation of the buffer signals in the midinfrared region. Values will be discussed in relation to the pH dependence of the midpoint potentials.

Yeast and human frataxin are processed to mature form in two sequential steps by the mitochondrial processing peptidase

Frataxin is a nuclear-encoded mitochondrial protein which is deficient in Friedreich's ataxia, a hereditary neurodegenerative disease. Yeast mutants lacking the yeast frataxin homologue (Yfh1p) show iron accumulation in mitochondria and increased sensitivity to oxidative stress, suggesting that frataxin plays a critical role in mitochondrial iron homeostasis and free radical toxicity. Both Yfh1p and frataxin are synthesized as larger precursor molecules that, upon import into mitochondria, are subject to two proteolytic cleavages, yielding an intermediate and a mature size form. A recent study found that recombinant rat mitochondrial processing peptidase (MPP) cleaves the mouse frataxin precursor to the intermediate but not the mature form (Koutnikova, H., Campuzano, V., and Koenig, M. (1998) Hum. Mol. Gen. 7, 1485-1489), suggesting that a different peptidase might be required for production of mature size frataxin. However, in the present study we show that MPP is solely responsible for maturation of yeast and human frataxin. MPP first cleaves the precursor to intermediate form and subsequently converts the intermediate to mature size protein. In this way, MPP could influence frataxin function and indirectly affect mitochondrial iron homeostasis.

Localization of acidic residues involved in the proton pumping activity of the bovine heart mitochondrial bc1 complex

Chemical modification of carboxyl residues in polypeptide subunits of the mitochondrial bc1 complex causes a decoupling effect, that is inhibition of the proton pumping activity, without affecting the rate of electron transfer to ferricytochrome c. The study presented here is aimed at localizing and identifying the residues whose modification results in decoupling of the complex. Glutamate-53 in subunit IX (the DCCD-binding protein) and aspartate-166 in the Rieske iron-sulfur protein are the residues modified by N,N'-dicyclohexylcarbodiimide (DCCD) and N-(ethoxycarbonyl)-2-ethoxy-1,2-dihydroquinoline (EEDQ), respectively. The results obtained also suggest that the carboxy-terminal sequence of the Core protein II, which is fairly rich in acidic residues, may also play a role in the vectorial proton translocation activity of the complex.

Mechanism of iron transport to the site of heme synthesis inside yeast mitochondria

The import of metals, iron in particular, into mitochondria is poorly understood. Iron in mitochondria is required for the biosynthesis of heme and various iron-sulfur proteins. We have developed an in vitro assay to follow the uptake of iron into isolated yeast mitochondria. By measuring the incorporation of iron into porphyrin by ferrochelatase in the matrix, we were able to define the mechanism of iron import. Iron uptake is driven energetically by a membrane potential across the inner membrane but does not require ATP. Only reduced iron is functional in generating heme. Iron cannot be preloaded in the mitochondrial matrix but rather has to be transported across the inner membrane simultaneously with the synthesis of heme, suggesting that ferrochelatase receives iron directly from the inner membrane. Transport of iron is inhibited by manganese but not by zinc, nickel, and copper ions, explaining why in vivo these ions are not incorporated into porphyrin. The inner membrane proteins Mmt1p and Mmt2p proposed to be involved in mitochondrial iron movement are not required for the supply of ferrochelatase with iron. Iron transport can be reconstituted efficiently in a membrane potential-dependent fashion in proteoliposomes that were formed from a detergent extract of mitochondria. Our biochemical analysis of iron import into yeast mitochondria provides the basis for the identification of components involved in transport.

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.

Aromatic amino acids in the Rieske iron-sulfur protein do not form an obligatory conduit for electron transfer from the iron-sulfur cluster to the heme of cytochrome c1 in the cytochrome bc1 complex

We have changed nine conserved aromatic amino acids by site-directed mutagenesis of the cloned iron-sulfur protein gene to determine if any of these residues form an obligatory conduit for electron transfer within the iron-sulfur protein of the yeast cytochrome bc1 complex. The residues include W111, F117, W152, F173, W176, F177, H184, Y205 and F207. Greater than 70% of the catalytic activity was retained for all of the mutated iron-sulfur proteins, except for those containing a W152L and a W176L-F177L double mutation, for which the activity was approximately 45%. The crystal structures of the bc1 complex indicate that F177 and H184 are at the surface of the iron-sulfur protein near the surface of cytochrome c1, but not directly in a linear pathway between the iron-sulfur cluster and the c1 heme. The pre-steady-state rates of reduction of cytochromes b and c1 in mutants in which F177 and H184 were changed to non-aromatic residues were approximately 70-85% of the wild-type rates. There was a large decrease in iron-sulfur protein levels in mitochondrial membranes resulting from the W152L mutation and the W176L-F177L double mutation, and a small decrease for the Y205L, W176L and F177L mutations. This indicates that the decreases in activity resulting from these amino acid changes are due to instability of the altered proteins. These results show that these aromatic amino acids are unnecessary for electron transfer, but several are required for structural stability.

Mt-Hsp70 homolog, Ssc2p, required for maturation of yeast frataxin and mitochondrial iron homeostasis

Here we show that the yeast mitochondrial chaperone Ssc2p, a homolog of mt-Hsp70, plays a critical role in mitochondrial iron homeostasis. Yeast with ssc2-1 mutations were identified by a screen for altered iron-dependent gene regulation and mitochondrial dysfunction. These mutants exhibit increased cellular iron uptake, and the iron accumulates exclusively within mitochondria. Yfh1p is homologous to frataxin, the human protein implicated in the neurodegenerative disease, Friedreich's ataxia. Like mutants of yfh1, ssc2-1 mutants accumulate vast quantities of iron in mitochondria. Furthermore, using import studies with isolated mitochondria, we demonstrate a specific role for Ssc2p in the maturation of Yfh1p within this organelle. This function for a mitochondrial Hsp70 chaperone is likely to be conserved, implying that a human homolog of Ssc2p may be involved in iron homeostasis and in neurodegenerative disease.

The chemistry and mechanics of ubihydroquinone oxidation at center P (Qo) of the cytochrome bc1 complex

The emerging X-ray structures of the cytochrome bc1 complexes from bovine and chicken heart mitochondria support the protonmotive Q-cycle as the overall electron- and proton-pathway within the cytochrome bc1 complex. The energy conserving reaction within this reaction scheme is the unique bifurcation of electron flow into a high potential and a low potential pathway occurring at the ubihydroquinone-oxidation center (center P or Qo). This step is prerequisite for the 'recycling' of every second electron across the membrane onto the ubiquinone-reduction center, which results in vectorial proton translocation. It has been shown that during steady-state the step controlling this reaction is the first deprotonation of ubihydroquinone and not, as proposed earlier, the formation of a highly unstable semiquinone species. Ubiquinone has not yet been detected at the ubihydroquinone-oxidation center of the protein structures now available, but the pocket seems spacious enough to accommodate two ubiquinone molecules. This is in line with recent enzymological studies, which have shown that not only two ubiquinones, but also two inhibitor molecules can bind to center P. The most striking result from the structures is that the hydrophilic domain of the 'Rieske' protein can be found in two different positions which seem to allow electron transfer between the iron-sulfur cluster and either ubiquinone binding at center P or heme c1. This provides strong support for the 'catalytic switch' model proposed earlier based on detailed analysis of inhibitor binding to cytochrome bc1 complex in different redox states.

The role of charged amino acids in the alpha1-beta4 loop of the iron-sulfur protein of the cytochrome bc1 complex of yeast mitochondria

Previous experiments using deletion mutants of the iron-sulfur protein had indicated that amino acid residues 138-153 might be involved in the assembly of this protein into the cytochrome bc1 complex. To determine which specific residues might be involved in the assembly process, charged amino acids located in the alpha1-beta4 loop of the iron-sulfur protein were mutated to uncharged residues and tryptophan 152 to phenylalanine. The mutant genes were used to transform yeast cells (JPJ1) lacking the iron-sulfur protein gene. Mutants R146I and W152F had almost undetectable growth in medium containing glycerol/ethanol, whereas mutants D143A, K148I, and D149A grew more slowly than the wild type. Activity of the cytochrome bc1 complex was decreased 50, 90, 67, 89, and 90% in mutants D143A, R146I, K148I, D149A, and W152F, respectively, but unchanged in mutants D139A, Q141I, D145L, and V147S. In all of these mutants except W152F, the cytochrome c1 content, determined by immunoblotting, was comparable with that of wild-type cells. However, immunoblotting revealed that the content of the iron-sulfur protein was decreased proportionately in the five mutants with lowered enzymatic activity and growth suggesting that these amino acids are critical for maintaining the stability of the iron-sulfur protein. The efficiency of assembly in vitro compared with the wild type determined by selective immunoprecipitation was unchanged in the mutants with the exception of R146I, D149A, and W152F where decreases of 80, 60, and 60%, respectively, were observed suggesting that these amino acids are critical for the proper assembly of the iron-sulfur protein into the bc1 complex.

Alteration of the midpoint potential and catalytic activity of the rieske iron-sulfur protein by changes of amino acids forming hydrogen bonds to the iron-sulfur cluster

The crystal structure of the bovine Rieske iron-sulfur protein indicates a sulfur atom (S-1) of the iron-sulfur cluster and the sulfur atom (Sgamma) of a cysteine residue that coordinates one of the iron atoms form hydrogen bonds with the hydroxyl groups of Ser-163 and Tyr-165, respectively. We have altered the equivalent Ser-183 and Tyr-185 in the Saccharomyces cerevisiae Rieske iron-sulfur protein by site-directed mutagenesis of the iron-sulfur protein gene to examine how these hydrogen bonds affect the midpoint potential of the iron-sulfur cluster and how changes in the midpoint potential affect the activity of the enzyme. Eliminating the hydrogen bond from the hydroxyl group of Ser-183 to S-1 of the cluster lowers the midpoint potential of the cluster by 130 mV, and eliminating the hydrogen bond from the hydroxyl group of Tyr-185 to Sgamma of Cys-159 lowers the midpoint potential by 65 mV. Eliminating both hydrogen bonds has an approximately additive effect, lowering the midpoint potential by 180 mV. Thus, these hydrogen bonds contribute significantly to the positive midpoint potential of the cluster but are not essential for its assembly. The activity of the bc1 complex decreases with the decrease in midpoint potential, confirming that oxidation of ubiquinol by the iron-sulfur protein is the rate-limiting partial reaction in the bc1 complex, and that the rate of this reaction is extensively influenced by the midpoint potential of the iron-sulfur cluster.

Chemical modification of the bovine mitochondrial bc1 complex reveals critical acidic residues involved in the proton pumping activity

Bovine heart ubiquinol-cytochrome c reductase (bc1 complex) was modified with N-(ethoxycarbonyl)-2-ethoxy-1,2-dihydroquinoline (EEDQ), which is a selective reagent for buried carboxyl groups. EEDQ treatment caused a loss of the proton pumping activity of liposome-reconstituted bc1 complex, without effect on the passive proton conductivity of the proteoliposomes. Although the decoupling effect produced on proton translocation was similar to that elicited by N,N'-dicyclohexylcarbodiimide (DCCD) modification of cytochrome b and subunit IX, EEDQ modified different subunits, namely the Core protein II and the iron-sulfur protein (ISP). A time-dependent increase of the labeling of both subunits was observed which was kinetically comparable with the decrease of the H+/e- ratio. Trypsin treatment of the complex showed that the EEDQ-modified carboxyl group in the ISP belongs to the protruding moiety of the protein, holding the Fe/S cluster. The results obtained show that critical acidic residues, located in different subunits of the bc1 complex, at both sides of the membrane, contribute to its proton pumping activity.

Conserved nonliganding residues of the Rhodobacter capsulatus Rieske iron-sulfur protein of the bc1 complex are essential for protein structure, properties of the [2Fe-2S] cluster, and communication with the quinone pool

The iron-sulfur (Fe-S) protein subunit of the bc1 complex, known as the Rieske protein, contains a high-potential [2Fe-2S] cluster ligated by two nitrogen and two sulfur atoms to its apoprotein. Earlier work indicated that in Rhodobacter capsulatus these atoms are provided by two cysteine (C133 and C153) and two histidine (H135 and H156) residues, located at the carboxyl-terminal end of the protein [Davidson, E., Ohnishi, T., Atta-Asafo-Adjei, E., & Daldal, F. (1992) Biochemistry 31, 3342-3351]. These ligands are part of the conserved sequences C133THLGC138 (box I) and C153PCHGS158 (box II) and affect the properties of the Fe-S protein and its [2Fe-2S] cluster. In this work, the role of amino acid side chains at positions 134 and 136, adjacent to the cluster ligands in box I, was probed by using site-directed mutagenesis and biophysical analyses. These positions were substituted with R, D, H, and G to probe the effect of charged, polar, large, and small amino acid side chains on the properties of the [2Fe-2S] cluster. Of the mutants obtained T134R, -H, and -G were photosynthetically competent (Ps+) but contained Fe-S proteins with redox midpoint potentials (Em7) 50-100 mV lower than that of a wild type strain. In contrast, T134D was Ps- and contained no detectable [2Fe-2S] cluster, although it reverted frequently to Ps+ by substitution of D with N. On the other hand, all L136 mutants were Ps-, the EPR characteristics of their [2Fe-2S] cluster were perturbed, and they were unable to sense the Qpool redox state or to bind stigmatellin properly. The overall data indicated that replacement of the amino acid side chain at position 134 of the Fe-S protein affects mainly the Em7 and oxygen sensitivity of the [2Fe-2S] cluster without abolishing its function, while substitutions at position 136 perturb drastically its ability to monitor the Qpool redox state and its interaction with the Qo site inhibitor stigmatellin. These two distinct phenotypes of box I T134 and L136 mutants are discussed with regard to the recently published three-dimensional structure of the water soluble part of the bovine heart mitochondrial Rieske Fe-S protein.

The amino-terminal portion of the Rieske iron-sulfur protein contributes to the ubihydroquinone oxidation site catalysis of the Rhodobacter capsulatus bc1 complex

The Rieske iron-sulfur (Fe-S) protein subunit of bc1 complexes contains in its carboxyl-terminal part two highly conserved hexapeptide motifs (box I and box II) that include the four amino acid ligands of its [2Fe-2S] cluster. In the preceding paper [Liebl, U., Sled, V., Brasseur, G., Ohnishi, T., & Daldal, F. (1997) Biochemistry 36, 11675-11684], the effects of mutations at two of the nonliganding residues [threonine (T) 134 and leucine (L) 136 in the Rhodobactercapsulatus Rieske Fe-S protein] of box I have been described. In this work, interactions between the occupants of the Qo site of the bc1 complex (UQ/UQH2 and the inhibitors stigmatellin and myxothiazol) and the [2Fe-2S] cluster of the Rieske Fe-S protein were probed by isolating photosynthesis-proficient (Ps+) revertants of the Ps- mutants L136R, -H, -D and -G. These revertants contained either a single substitution at the original position 136 or an additional mutation located in the amino-terminal part of the Fe-S protein at either position 44 or 46. The same-site revertants L136A and -Y grew well under photosynthetic conditions and contained highly active bc1 complexes but exhibited modified EPR spectra both in the presence and in the absence of stigmatellin. Unexpectedly, they were highly resistant to stigmatellin (StiR) and hypersensitive to myxothiazol (MyxHS) in vivo, demonstrating for the first time that mutations located in the Fe-S subunit confer resistance to stigmatellin. The [2Fe-2S] cluster of the same-site revertants responded weakly to the Qpool redox state and had redox midpoint potential (Em7) values (around 265 mV) lower than those of their wild type counterpart (about 310 mV). On the other hand, the second-site revertants L136H/V44L, L136G/V44F, and L136G/A46T, -V, or -P supported photosynthetic growth poorly, were StiR and MyxHS, and contained barely active bc1 complexes. Like the same-site revertants, they exhibited modified EPR spectra both in the presence and in the absence of stigmatellin and had perturbed Qo site occupancy. In addition, they contained substoichiometric amounts of the Fe-S protein with respect to the other subunits of the bc1 complex. The Em7 values of the [2Fe-2S] cluster of these double mutants were lower (around 245 mV) than that of the wild type strain but appreciably higher than those of their Ps- parents (about 200 mV for L136G). In order to define the molecular nature of the suppression mediated by the second-site mutations, the single mutants V44L and -F and A46T and -V were constructed in the absence of the original mutations at position 136. These mutants behaved like a wild type strain with respect to their Ps+ growth ability, inhibitor sensitivity, EPR spectra of their [2Fe-2S] cluster, and response to stigmatellin or to the Qpool redox state. But surprisingly, the Em7 values of their [2Fe-2S] cluster were much higher (about 385 mV) than that of a wild type strain. These findings demonstrated for the first time that the amino-terminal part of the Rieske Fe-S protein encompassing residues 44 and 46 is important not only for the structure and function of the Qo site of the bc1 complex but also for the properties of its [2Fe-2S] cluster.

Molecular mechanisms of doxorubicin-induced cardiomyopathy. Selective suppression of Reiske iron-sulfur protein, ADP/ATP translocase, and phosphofructokinase genes is associated with ATP depletion in rat cardiomyocytes

Doxorubicin, a cardiotoxic antineoplastic, disrupts the cardiac-specific program of gene expression (Kurabayashi, M., Dutta, S., Jeyaseelan, R., and Kedes, L. (1995) Mol. Cell. Biol. 15, 6386-6397). We have now identified neonatal rat cardiomyocyte mRNAs rapidly sensitive to doxorubicin, or its congener daunomycin, including transcripts of nuclear genes encoding enzymes critical in production of energy in cardiomyocytes: ADP/ATP translocase, a heart- and muscle-specific isoform; Reiske iron-sulfur protein (RISP), a ubiquitously expressed electron transport chain component; and a muscle isozyme of phosphofructokinase. Loss of these mRNAs following doxorubicin or daunomycin is evident as early as 2 h and precedes significant reduction of intracellular ATP. ATP levels in control cardiomyocytes (17.9 +/- 2.9 nM/mg of protein) fall only after 14 h and reach residual levels of 10.4 +/- 0.9 nM (doxorubicin; p = <0.006) and 6.7 +/- 1.9 nM (daunomycin; p = <0. 001) by 24 h. Loss of mRNAs generating ATP was highly selective since mRNAs for other energy production enzymes, (cytochrome c, cytochrome b, and malate dehydrogenase), and genes important in glycolysis (pyruvate kinase and glyceraldehyde-3-phosphate dehydrogenase) were unaffected even at 24 and 48 h. The drugs had no effect on levels of ubiquitously expressed RISP mRNA in fibroblasts. These findings could link doxorubicin-induced damage to membranes and signaling pathways with 1) suppression of transcripts encoding myofibrillar proteins and proteins of energy production pathways and 2) depletion of intracellular ATP stores, myofibrillar degeneration, and related cardiotoxic effects.

Antimycin resistance and ubiquinol cytochrome c reductase instability associated with a human cytochrome b mutation

Progressive exercise intolerance was associated with a decreased maximal rate of ubiquinol cytochrome c reductase (complex III) activity in the muscle mitochondria of the studied patient and with a thirty five-fold increase in the I50 for antimycin A. In contrast, myxothiazol sensitivity was not altered. Complex III activity was stable at 37 degrees C, but progressively decreased at 4 degrees C. An heteroplasmic G to A mutation at position 15615 of the mitochondrial DNA, resulting in the replacement of the highly conserved Gly290 in cytochrome b by Asp, was identified. Histochemical studies showed increased cytochrome oxidase and succinate dehydrogenase activities under the sarcolemma of type I fibres. After partial extraction of mitochondria from the muscle, the residual pellet contained a lower percentage of the mutation than did whole muscle, suggesting that the percentage of mutation is higher in the most readily extracted mitochondria, most probably present under the sarcolemma. In the current 8 transmembrane helix model of cytochrome b, Gly290 lies at the end of the sixth transmembrane helix, facing the intermembrane space and close to the presumed sites of interaction between cytochrome b, the iron-sulfur protein and the 9.5 kDa protein. Since immunoblotting experiments showed a relative decrease in the proportions of these three subunits in the patient's mitochondria compared with the other complex III subunits, it is probable that the complex III instability and the relative decrease in these subunits are related to the mutation. The relationship between the decrease in the apparent affinity for antimycin A and the instability of complex III are discussed.

Characterization and crystallization of the lumen side domain of the chloroplast Rieske iron-sulfur protein

A soluble, 139-residue COOH-terminal polypeptide fragment of the Rieske iron-sulfur protein of the cytochrome b6f complex from spinach chloroplasts was obtained by limited proteolysis of the complex and a two-step chromatography purification protocol. The purified Rieske iron-sulfur protein fragment was characterized by: (i) a single NH2-terminal sequence, NH2-Phe-Val-Pro-Pro-Gly-Gly, starting with residue 41 of the intact Rieske protein; (ii) a single molecular weight species determined by mass spectrometry with a molecular weight of 14,620 +/- 2 without the [2Fe-2S] cluster; (iii) an optical absorbance spectrum with redox- and pH-dependent maxima and minima; and (iv) a reduced-oxidized optical difference spectrum characterized by DeltaepsilonmM = 3.8 mM-1 cm-1 for DeltaA at 394 versus 409 nm, which was used to determine the midpoint oxidation-reduction potential, which is +359 +/- 7 mV at 25 degrees C from pH 5.5-6.5, and +319 +/- 2 mV at pH 7, with an apparent pKox = 6.5 +/- 0.2 for the oxidized protein. The EPR spectrum measured at 17 K was characterized by the g values, gz = 2.03 and gy = 1.90, and a broad band centered at gx approximately 1.74, very similar or identical to those of the Rieske cluster in the b6f complex, implying that the environment of the [2Fe-2S] cluster is similar to that in the complex. Midpoint potential determination by low temperature EPR yielded a redox midpoint potential (Em) of +365-375 mV of the soluble Rieske fragment at pH 6 and 7 and an Em of +295-300 mV of the Rieske cluster in the cytochrome b6f complex at pH 6 and 7. The Em difference implies that the environment of the cluster in the soluble Rieske fragment is slightly more polar than that of the cluster in the intact complex. Single crystals of the Rieske polypeptide were obtained that are capable of x-ray diffraction to atomic resolution (<2.5 A), contain one molecule per asymmetric unit, a solvent content of approximately 30%, and belong to the triclinic space group P1 with cell dimensions, a = 29.1 A, b = 31.9 A, c = 35.8 A, alpha = 95.6 degrees, beta = 107.1 degrees, gamma = 117.3 degrees.

Dissociation of import of the Rieske iron-sulfur protein into Saccharomyces cerevisiae mitochondria from proteolytic processing of the presequence

The correlation between the import of the Rieske iron-sulfur protein into the mitochondrial matrix and processing of the precursor protein by matrix processing peptidase was investigated using high concentrations of metal chelators and iron-sulfur protein in which the recognition site for the matrix processing peptidase was destroyed by site-directed mutagenesis. High concentrations of EDTA and o-phenanthroline inhibit import of iron-sulfur protein into the matrix. The non-chelating structural isomers m-phenanthroline and p-phenanthroline inhibit import similar to o-phenanthroline, indicating that inhibition of import is mainly independent of the metal chelating ability of the compounds. Iron-sulfur protein in which the recognition site for the matrix processing peptidase had been destroyed by a point mutation was efficiently imported into the matrix space. Import of this mutant iron-sulfur protein was inhibited by the same concentrations of EDTA and o-phenanthroline which inhibit import of the wild-type protein. These results indicate that import of the iron-sulfur protein into the mitochondrial matrix is independent of proteolytic processing of the presequence, and that o-phenanthroline together with EDTA inhibits import of iron-sulfur protein into the matrix space of mitochondria by inhibiting a step other than proteolysis of the presequence.

In vitro import of the Rieske iron-sulfur protein by trypanosome mitochondria

Most of the proteins present in the mitochondrion are imported to that location from the cytosol. While this process has been studied extensively in fungal and mammalian systems, little work has been done in other eukaryotic organisms. We are particularly interested in the Trypanosoma brucei system because this organism developmentally regulates mitochondrial function during its life cycle and because one of the imported proteins lacks a conventional targeting sequence. We report here the development of an in vitro import system using crude trypanosome mitochondria and a nuclear encoded, mitochondrial protein. Import of the Rieske iron-sulfur protein subunit of the cytochrome c reductase complex requires a membrane potential, ATP, and a protein component on the mitochondrial surface. The precursor protein is sequentially processed to the mature form in two steps by peptidases that require divalent metal ions for activity. As in other eukaryotic systems, the first processing event occurs inside the inner membrane and is probably catalyzed by a matrix-processing protease. Surprisingly, the second processing activity is located outside the inner membrane. Both processing steps require ATP but are independent of a membrane potential. We suggest that the trypanosome iron-sulfur protein is imported along a "conservative sorting pathway" but that the assembly mechanism of the reductase complex may be unique to trypanosomes.

Functional implications of the structure of the 'Rieske' iron-sulfur protein of bovine heart mitochondrial cytochrome bc1 complex

Recently, we have determined the structure of the catalytic domain of the 'Rieske' iron-sulfur protein of bovine heart mitochondrial bc1 complex at 1.5 A resolution (Iwata, S., Saynovits, M., Link, T.A. and Michel, H. (1996) Structure, 4, 567-579). This is the first structure of a bis-histidine coordinated [2Fe-2S] cluster. The spectroscopic, electrochemical, and functional implications of the structure will be discussed.

Energy conservation by bifurcated electron-transfer in the cytochrome-bc1 complex

The overall electron- and proton-pathways within the cytochrome-bc1 complex are described by a widely accepted mechanism known as the protonmotive Q-cycle. Within this reaction scheme, the unique bifurcation of electron flow into a high potential and a low potential pathway occurring at the ubihydroquinone-oxidation center is the energy conserving reaction. It is this reaction, which results in vectorial proton translocation, as it allows the 'recycling' of every second electron across the membrane onto the ubiquinone-reduction center. However, the Q-cycle reaction scheme does not address the detailed chemistry of this central step. Based on a structural model of the ubihydroquinone-oxidation pocket and the assumption that the reaction involves two ubiquinone molecules in a stacked configuration, here I propose a detailed chemical model for the reactions occurring during steady-state catalysis. In this proton-gated charge-transfer mechanism the reaction is controlled by the deprotonation of the substrate ubihydroquinone and not, as proposed earlier, by the formation of a highly unstable semiquinone species.

Heterologous complementation of a Rieske iron-sulfur protein-deficient Saccharomyces cerevisiae by the Rip1 gene of Schizosaccharomyces pombe

A cDNA carrying the Rip1 gene, which encodes the Rieske iron-sulfur protein of Schizosaccharomyces pombe, has been cloned by complementing the respiratory deficiency of a Saccharomyces cerevisiae strain in which the endogenous copy of the RIP1 gene has been deleted. The deduced amino acid sequences of the S. pombe and S. cerevisiae iron-sulfur proteins are 50% identical, with the highest region of identity being in the C termini of the proteins, where the 2Fe:2S cluster is bound. When expressed in the S. cerevisiae deletion strain, the S. pombe iron-sulfur protein restores 25-30% of the ubiquinol-cytochrome c reductase activity. The kinetics of cytochrome c reduction, the effects of inhibitors which act at defined sites in the cytochrome bc1 complex, and the optical properties of cytochrome b in membranes from the S. cerevisiae deletion strain complemented with S. pombe iron-sulfur protein indicate that the S. pombe protein interacts with cytochrome b to restore an apparently normal ubiquinol oxidase site, but that interaction between the iron-sulfur protein and cytochrome c1 is partially impaired. This is the first heterologous replacement of an electron transfer protein in a respiratory enzyme complex in S. cerevisiae.

Bifurcated ubihydroquinone oxidation in the cytochrome bc1 complex by proton-gated charge transfer

The unique bifurcation of electron flow at the ubihydroquinone-oxidation center of the cytochrome bc1 complex is the energy-conserving reaction of the protonmotive Q- cycle and is prerequisite to vectorial proton translocation. The widely accepted Q-cycle reaction scheme describes the overall electron and proton pathways, but does not address the detailed chemistry of this central step. Based on a model of the ubihydroquinone-oxidation pocket containing two ubiquinone molecules in a stacked configuration, a detailed model for the reactions during steady-state catalysis is proposed. In this proton-gated charge-transfer mechanism the reaction is controlled by the deprotonation of the substrate ubihydroquinone.

Structure of a water soluble fragment of the 'Rieske' iron-sulfur protein of the bovine heart mitochondrial cytochrome bc1 complex determined by MAD phasing at 1.5 A resolution

BACKGROUND

The 'Rieske' iron-sulfur protein is the primary electron acceptor during hydroquinone oxidation in cytochrome bc complexes. The spectroscopic and electrochemical properties of the 'Rieske' [2Fe-2S] cluster differ significantly from those of other iron-sulfur clusters. A 129-residue water soluble fragment containing the intact [2Fe-2S] cluster was isolated following proteolytic digestion of the bc1 complex and used for structural studies.

RESULTS

The structure of the Rieske iron-sulfur fragment containing the reduced [2Fe-2S] cluster has been determined using the multiwavelength anomalous diffraction (MAD) technique and refined at 1.5 A resolution. The fragment has a novel overall fold that includes three sheets of beta strands. The iron atoms of the [2Fe-2S] cluster are coordinated by two cysteine (Fe-1) and two histidine (Fe-2) residues, respectively, with the histidine ligands completely exposed to the solvent. This is in contrast to the four cysteine coordination pattern observed in previously characterised [2Fe-2S] ferredoxins. The cluster-binding fold is formed by two loops connected by a disulfide bridge; these loops superpose with the metal-binding loops of rubredoxins. The environment of the cluster is stabilised by an extensive hydrogen-bond network.

CONCLUSIONS

The high-resolution structure supports the proposed coordination pattern involving histidine ligands and provides a basis for a detailed analysis of the spectroscopic and electrochemical properties. As the cluster is located at the tip of the protein, it might come into close contact with cytochrome b. The exposed N epsilon atoms of the histidine ligands of the cluster are readily accessible to quinones and inhibitors within the hydroquinone oxidation (QP) pocket of the bc1 complex and may undergo redox-dependent protonation/deprotonation.

CMP-N-acetylneuraminic acid hydroxylase: the first cytosolic Rieske iron-sulphur protein to be described in Eukarya

Electron paramagnetic resonance (EPR) spectroscopy and analysis of the primary structure of the CMP-N-acetylneuraminic acid hydroxylase revealed that this enzyme is the first iron-sulphur protein of the Rieske type to be found in the cytosol of Eukarya. The dithionite-reduced hydroxylase exhibited an EPR signal known to be characteristic for a Rieske iron-sulphur centre (2Fe-2S), the g-values being 1.78, 1.91 and 2.01, respectively. An analysis of the primary structure of the hydroxylase led to the identification of an amino acid sequence, known to be characteristic for Rieske proteins. Furthermore, possible binding sites for cytochrome b5, the substrate CMP-Neu5Ac and a mononuclear iron centre were also identified.

A requirement for matrix processing peptidase but not for mitochondrial chaperonin in the covalent attachment of FAD to the yeast succinate dehydrogenase flavoprotein

Succinate dehydrogenase (EC 1.3.99.1) in the yeast Saccharomyces cerevisiae is a mitochondrial heterotetramer containing a flavoprotein subunit with an 8alpha-N(3)-histidyl-linked FAD cofactor. The covalent linkage of the FAD is necessary for activity. We have developed an in vitro assay that measures the flavinylation of the flavoprotein precursor in mitochondrial matrix fractions. Flavoprotein modification does not depend on translocation across a membrane, but it does require proteolytic processing by the mitochondrial processing peptidase prior to flavin attachment. Since ATP depletion, N-ethylmaleimide, or proteinase treatments of matrix fractions inhibit flavoprotein modification, at least one additional matrix protein component appears to be required. Having previously suggested that the flavoprotein begins folding before FAD attachment occurs, we tested whether the mitochondrial chaperonin, heat shock protein 60, might be necessary. Co-immunoprecipitation of the flavoprotein and the chaperonin demonstrate that the proteins do indeed interact. However, immunodepletion of the chaperonin from matrix fractions does not inhibit FAD attachment. Nonprotein components are also required for flavoprotein modification. In addition to ATP, effector molecules such as succinate, fumarate, or malate also stimulate modification. Together, these results suggest that FAD addition is an early event in succinate dehydrogenase assembly.

Structure-function relationships of the mitochondrial bc1 complex in temperature-sensitive mutants of the cytochrome b gene, impaired in the catalytic center N

Seven new structures of cytochrome b have been recently identified by isolating and sequencing revertants from cytochrome b respiratory deficient mutants (Coppée, J. Y., Brasseur, G., Brivet-Chevillotte, P., and Colson, A. M. (1994) J. Biol. Chem. 269, 4221-4226). These mutations are located in the center N domain (QN). All the revertants exhibited a modified heme b562 maximum, confirming that part of the NH2-terminal region is in the vicinity of the extramembranous loop between helices IV-V and heme b562. Based on measurements performed on the maximal activities occurring in each segment of the respiratory chain, the decrease observed in the NADH oxidase activities of several revertants was correlated with some bc1 complex activity impairments; this may also explain why a moderate decrease in bc1 complex activity does not limit the succinate oxidase activity. The decrease in the rate of reduction of cytochrome b via the center N pathway is responsible for the impairment of the bc1 complex activity of these revertants. The three double-mutated revertants (S206L/N208K or -Y; S206L/W30C) are temperature-sensitive in vivo, and their mitochondria like that of the original mutant S206L are thermosensitive in vitro. Isolating the W30C mutation does not yield a thermosensitive phenotype: the replacement of serine 206 by leucine is therefore responsible for the thermoinstability of these strains; this temperature sensitivity is reinforced by additional mutations N208K or N208Y, and not by W30C. These data suggest that serine 206 and asparagine 208 are involved in the thermostability of the protein. When bc1 complex activity is lost after incubating mitochondria at a nonpermissive temperature (37 degrees C), heme b is still present, but can no longer be reduced by physiological substrate. The progressive loss of bc1 complex activity seems to be initially linked to a change in the tertiary structure of cytochrome b, which occurs drastically at center N and much more slowly at center P, as shown by kinetic study on the two cytochrome b redox pathways.

The trypanosomatid Rieske iron-sulfur proteins have a cleaved presequence that may direct mitochondrial import

We have cloned the gene that encodes subunit 4 of the T. brucei cytochrome-c reductase complex and a fragment of the C. fasciculata subunit 4 cDNA and have shown that subunit 4 is the Rieske iron-sulfur protein. The cleaved presequences of the trypanosomatid iron-sulfur proteins resemble conventional mitochondrial targeting presequences but are smaller than other eukaryotic iron-sulfur protein signal peptides.

Prediction and identification of new natural substrates of the yeast mitochondrial intermediate peptidase

Most mitochondrial precursor proteins are processed to the mature form in one step by mitochondrial processing peptidase (MPP), while a subset of precursors destined for the matrix or the inner membrane are cleaved sequentially by MPP and mitochondrial intermediate peptidase (MIP). We showed previously that yeast MIP (YMIP) is required for mitochondrial function in Saccharomyces cerevisiae. To further define the role played by two-step processing in mitochondrial biogenesis, we have now characterized the natural substrates of YMIP. A total of 133 known yeast mitochondrial precursors were collected from the literature and analyzed for the presence of the motif RX(decreases)(F/L/I)XX(T/S/G)XXXX(decreases), typical of precursors cleaved by MPP and MIP. We found characteristic MIP cleavage sites in two distinct sets of proteins: respiratory components, including subunits of the electron transport chain and tricarboxylic acid cycle enzymes, and components of the mitochondrial genetic machinery, including ribosomal proteins, translation factors, and proteins required for mitochondrial DNA metabolism. Representative precursors from both sets were cleaved to predominantly mature form by mitochondrial matrix or intact mitochondria from wild-type yeast. In contrast, intermediate-size forms were accumulated upon incubation of the precursors with matrix from mip1 delta yeast or intact mitochondria from mip1ts yeast, indicating that YMIP is necessary for maturation of these proteins. Consistent with the fact that some of these substrates are essential for the maintenance of mitochondrial protein synthesis and mitochondrial DNA replication, mip1 delta yeast undergoes loss of functional mitochondrial genomes.

Functional analysis of a recently originating, atypical presequence: mitochondrial import and processing of GUS fusion proteins in transgenic tobacco and yeast

A gene family of at least five members encodes the tobacco mitochondrial Rieske Fe-S protein (RISP). To determine whether all five RISPs are translocated to mitochondria, fusion proteins containing the putative presequences of tobacco RISPs and Escherichia coli beta-glucuronidase (GUS) were expressed in transgenic tobacco, and the resultant GUS proteins were localized by cell fractionation. The amino-terminal 75 and 71 residues of RISP2 and RISP3, respectively, directed GUS import into mitochondria, where fusion protein processing occurred. The amino-terminal sequence of RISP4, which contains an atypical mitochondrial presequence, can translocate the GUS protein specifically into tobacco mitochondria with apparently low efficiency. Consistent with the proposal of a conserved mechanism for protein import in plants and fungi, the tobacco RISP3 and RISP4 presequences can direct import and processing of a GUS fusion protein in yeast mitochondria. Plant presequences, however, direct mitochondrial import in yeast less efficiently than the yeast presequence, indicating subtle differences between the plant and yeast mitochondrial import machineries. Our studies show that import of RISP4 may not require positively charged amino acid residues and an amphipathic secondary structure; however, these structural properties may improve the efficiency of mitochondrial import.

Molecular structure of the 8.0 kDa subunit of cytochrome-c reductase from potato and its delta psi-dependent import into isolated mitochondria

The cytochrome-c reductase (EC 1.10.2.2) of the mitochondrial respiratory chain couples electron transport from ubiquinol to cytochrome c with proton translocation across the inner mitochondrial membrane. The enzyme from potato was shown to be composed of 10 subunits. Isolation and characterization of cDNA clones for the second smallest subunit reveal an open reading frame of 216 bp encoding a protein of 8.0 kDa. The protein exhibits similarities to a 7.2/7.3 kDa subunit of cytochrome-c reductase from bovine and yeast, that is localized on the intermembrane space side of the enzyme complex. It also shows similarity to a previously unidentified 7.8 kDa protein of cytochrome-c reductase from Euglena. The potato 8.0 kDa protein has a segmental structure, as its sequence can be divided into four parts, each comprising a central Arg-(Xaa)5-Val motif. N-terminal sequencing of the mature 8.0 kDa proteins indicates the absence of a cleavable mitochondrial targeting sequence. Import of the in vitro synthesized 8.0 kDa protein into isolated potato mitochondria confirms the lack of a presequence and reveals a dependence of the transport on the membrane potential delta psi across the inner mitochondrial membrane. These features are unique among the intermembrane space proteins known so far.

Crystallization of mitochondrial cytochrome b-c1 complex from gel with or without reduced pressure

Cytochrome b-c1 complex (ubiquinol-cytochrome c reductase) of beef heart mitochondria has been crystallized. Crystals grown in capillary tubes diffracted X-rays from a laboratory source to a resolution of 7 A and synchrotron radiation to a resolution of 4.5 A in the presence of mother liquor. However, the movement of crystals in the mother liquor makes data collection very difficult. Removal of the mother liquor from the crystals causes severe loss of diffraction quality. To circumvent these difficulties we have recently developed a method for crystallization of the cytochrome b-c1 complex from a gel. The sizes, shapes and diffraction qualities of crystals grown in gel approach those of crystals obtained from liquid. Preliminary experiments on a Xuong-Hamlin area detector indicate that these crystals have the symmetry of a body centered tetragonal space group with cell constants a = b = 157 A, c = 590 A. Assuming eight cytochrome b-c1 complex dimers per unit cell, the crystals have a solvent content of 70% (v/v). Under reduced pressure the crystallization time is significantly decreased. Although crystals obtained under reduced pressure are generally smaller, the shorter crystallization time provides an opportunity to explore more crystallization conditions.