Structure and function of the mitochondrial bc1 complex. Properties of the complex in temperature-sensitive cor1 mutants

The properties of the ubiquinol-cytochrome c reductase complex (bc1 complex) have been studied in respiratory defective mutants of Saccharomyces cerevisiae bearing lesions in the core 1 subunit. All the cor1 mutants examined have greatly reduced concentrations of mitochondrial cytochrome b and display succinate-cytochrome c reductase activities near the limits of detection. Two mutants (E576 and C7), however, had 5% of wild type activity when the cells were grown at 23 degrees C, but not at 37 degrees C. The temperature-sensitive phenotype was determined to result from substitution of either Arg or Glu for Gly68 of the core 1 subunit. The respiratory competent revertants E576/R8 and C7/R4 derived from E576 and C7 retain the temperature sensitivity of the original mutants. Both revertants are temperature sensitive in vivo, but only mitochondria isolated from E576/R8 are temperature sensitive in vitro. The bc1 complex of mitochondria isolated from this revertant displays a normal value of the ratio Kcat/Km for cytochrome c and four times higher than the wild type for duroquinol. The succinate-cytochrome c reductase activity of E576/R8 is almost completely abolished after incubation at 37 degrees C for 90 min. It is inferred that the quaternary structure of ubiquinol-cytochrome c reductase complex is more labile at the nonpermissive temperature in the mutant and undergoes an alteration such that cytochrome b is no longer able to receive electrons through either the "o" or the "i" site pathway. The temperature lability and kinetic properties of the mutant enzyme point to a requirement of the core 1 not only for assembly but also for the catalytic activity of the complex.     

Pleiotropic effects of the yeast Sal1 and Aac2 carriers on mitochondrial function via an activity distinct from adenine nucleotide transport

In Saccharomyces cerevisiae, SAL1 encodes a Ca2+ -binding mitochondrial carrier. Disruption of SAL1 is synthetically lethal with the loss of a specific function associated with the Aac2 isoform of the ATP/ADP translocase. This novel activity of Aac2 is defined as the V function (for Viability of aac2 sal1 double mutant), which is independent of the ATP/ADP exchange activity required for respiratory growth (the R function). We found that co-inactivation of SAL1 and AAC2 leads to defects in mitochondrial translation and mitochondrial DNA (mtDNA) maintenance. Additionally, sal1Delta exacerbates the respiratory deficiency and mtDNA instability of ggc1Delta, shy1Delta and mtg1Delta mutants, which are known to reduce mitochondrial protein synthesis or protein complex assembly. The V function is complemented by the human Short Ca2+ -binding Mitochondrial Carrier (SCaMC) protein, SCaMC-2, a putative ATP-Mg/Pi exchangers on the inner membrane. However, mitochondria lacking both Sal1p and Aac2p are not depleted of adenine nucleotides. The Aac2R252I and Aac2R253I variants mutated at the R252-254 triplet critical for nucleotide transport retain the V function. Likewise, Sal1p remains functionally active when the R479I and R481I mutations were introduced into the structurally equivalent R479-T480-R481 motif. Finally, we found that the naturally occurring V-R+ Aac1 isoform of adenine nucleotide translocase partially gains the V function at the expense of the R function by introducing the mutations P89L and A96 V. Thus, our data support the view that the V function is independent of adenine nucleotide transport associated with Sal1p and Aac2p and this evolutionarily conserved activity affects multiple processes in mitochondria.     

Functional Analysis of Yeast bcs1 Mutants Highlights the Role of Bcs1p-Specific Amino Acids in the AAA Domain

The mitochondrial protein Bcs1p is conserved from Saccharomyces cerevisiae to humans and its C-terminal region exhibits an AAA (ATPases associated with diverse cellular activities) domain. The absence of the yeast Bcs1p leads to an assembly defect of the iron-sulfur protein (ISP) subunit within the mitochondrial respiratory complex III, whereas human point mutations located all along the protein cause various pathologies. We have performed a structure-function analysis of the yeast Bcs1p by randomly generating a collection of respiratory-deficient point mutants. We showed that most mutations are in the C-terminal region of Bcs1p and have localized them on a theoretical three-dimensional model based on the structure of several AAA proteins. The mutations can be grouped into classes according to their respiratory competence and their location on the three-dimensional model. We have further characterized five mutants, each substituting an amino acid conserved in yeast and mammalian Bcs1 proteins but not in other AAA proteins. The effects on respiratory complex assembly and Bcs1p accumulation were analyzed. Intragenic and extragenic compensatory mutations able to restore complex III assembly to the mutants affecting the AAA domain were isolated. Our results bring new insights into the role of specific residues in critical regions that are also conserved in the human Bcs1p. We show that (1) residues located at the junction between the Bcs1p-specific and the AAA domains are important for the activity and stability of the protein and (2) the residue F342 is important for interactions with other partners or substrate proteins.     

Cloning and sequencing of a cDNA encoding the Rieske iron-sulfur protein of bovine heart mitochondrial ubiquinol-cytochrome c reductase

Two cDNA clones encoding bovine heart mitochondrial Rieske iron-sulfur protein were obtained by immunological screening of a bovine heart cDNA expression library in lambda gt11 with antiserum directed against Rieske iron-sulfur protein isolated from bovine heart mitochondrial ubiquinol-cytochrome c reductase. The cDNA inserts were 1005 and 1100 base pairs with an open reading frame of 807 base pairs which encoded a 196-amino acid mature Rieske iron-sulfur protein and a 73-amino acid presequence. The amino acid sequence of Rieske iron-sulfur protein deduced from nucleotide sequencing is the same as that obtained from protein sequencing except at residues #73 and #191 which are Ser and Asp instead of Ala and Gly, respectively.     

Schizosaccharomyces pombe homologs of the Saccharomyces cerevisiae mitochondrial proteins Cbp6 and Mss51 function at a post-translational step of respiratory complex biogenesis

Complexes III and IV of the mitochondrial respiratory chain contain a few key subunits encoded by the mitochondrial genome. In Saccharomyces cerevisiae, fifteen mRNA-specific translational activators control mitochondrial translation, of which five are conserved in Schizosaccharomyces pombe. These include homologs of Cbp3, Cbp6 and Mss51 that participate in translation and the post-translational steps leading to the assembly of respiratory complexes III and IV. In this study we show that in contrast to budding yeast, Cbp3, Cbp6 and Mss51 from S. pombe are not required for the translation of mitochondrial mRNAs, but fulfill post-translational functions, thus probably accounting for their conservation.     

Essential role of the Vp2 and Vp3 DNA-binding domain in simian virus 40 morphogenesis.

Both a DNA-binding domain and a Vp1 interactive determinant have been mapped to the carboxy-terminal 40 residues of the simian virus 40 (SV40) minor capsid proteins, Vp2 and Vp3 (Vp2/3), with the last 13 residues being necessary for these activities. The role of this DNA-binding domain in SV40 morphogenesis and the ability to separate these two signals were investigated by mutagenesis and assessment of the activity and viability of the mutants. The carboxy-terminal 40 residues of Vp2/3 were expressed as a polyhistidine fusion protein, and five basic residues at the extreme carboxy terminus (Vp3 residues K226, R227, R228, R230, and R233) were mutagenized. The wild-type fusion protein bound DNA with a Kd of 3 x 10(-8) identical to that of the full-length Vp3. Mutant proteins containing either one to three or four amino acid substitutions bound DNA 4- to 7-fold or 20- to 30-fold less well, respectively, than the wild-type protein did. The most severe point mutants showed residual DNA binding similar to that of a truncated protein which lacks the entire 13 carboxy-terminal residues. All of the point mutants were able to interact with Vp1, indicating that the two signals within this region are mediated by different residues. When the mutations were placed into the context of the viral DNA and introduced into cells, all the structural proteins were expressed and localized correctly. Not all, however, were viable: mutant genomes whose Vp2/3 bound DNA with intermediate affinities formed plaques just as well as wild-type SV40 DNA did, but three mutants showing greatly reduced DNA binding failed to form plaques at all. These results are consistent with the hypothesis that Vp2/3 plays an essential role in SV40 virion assembly in the nucleus.     

Immunochemical study of subunit VI (Mr 13,400) of mitochondrial ubiquinol-cytochrome c reductase.

A preparation containing the Mr 13,400 protein (subunit VI), phospholipid, and ubiquinone was isolated from bovine heart mitochondrial ubiquinol-cytochrome c reductase by a procedure involving Triton X-100 and urea solubilization, calcium phosphate-cellulose column chromatography at different pHs, acetone precipitation, and decanoyl-N-methylglucamide-sodium cholate extraction. The protein in this preparation corresponds to subunit VI of ubiquinol-cytochrome c reductase resolved in the sodium dodecyl sulfate-polyacrylamidce gel electrophoresis system of Sch?gger et al. (1987, FEBS Lett. 21, 161-168) and has the same amino acid sequence as that of the Mr 13,400 protein reported by Wakabayashi et al. (1985, J. Biol. Chem. 260, 337-343). The phospholipid and ubiquinone present in the preparation copurify with but are not intrinsic components of, the Mr 13,400 protein. This preparation has a potency and behavior identical to that of a free phospholipid preparation in restoring activity to delipidated ubiquinol-cytochrome c reductase. Antibodies against Mr 13,400 react only with Mr 13,400 protein and complexes which contain it. They do not inhibit intact, lipid-sufficient ubiquinol-cytochrome c reductase. However, when delipidated ubiquinol-cytochrome c reductase is incubated with antibodies prior to reconstitution with phospholipid, a 55% decrease in the restoration activity is observed, indicating that the catalytic site-related epitopes of the Mr 13,400 protein are buried in the phospholipid environment. Antibodies against Mr 13,400 cause an increase of apparent Km for ubiquinol-2 in ubiquinol-cytochrome c reductase. When mitoplasts or submitochondrial particles are exposed to a horseradish peroxidase conjugate of the Fab' fragment of anti-Mr 13,400 antibodies, peroxidase activity is found mainly in the submitochondrial particles preparation; little activity is detected in mitoplasts. This suggests that the Mr 13,400 protein is extruded toward the matrix side of the membrane.     

Assembly of the mitochondrial membrane system. Analysis of structural mutants of the yeast coenzyme QH2-cytochrome c reductase complex

Coenzyme QH2-cytochrome c reductase is a multisubunit complex of the mitochondrial respiratory chain. Mutants of Saccharomyces cerevisiae with lesions in cytochromes b, c1, the non-heme iron protein, and the noncatalytic subunits have been used to study several aspects of the assembly of the complex. Strains with mutations in single subunits exhibit a variety of different phenotypes. Mutants in the 17-kDa (core 3) subunit grow normally on a nonfermentable substrate indicating that this component is not essential for either enzymatic activity or assembly of the enzyme. Mutations in all the other subunits express a respiratory-deficient phenotype and the absence of detectable enzyme activity. Among the respiratory-defective strains, some have mature cytochrome b (non-heme iron protein and cytochrome c1 mutants), while other mutants lack spectrally detectable cytochrome b and have reduced levels of the apoprotein (mutants in the 44-, 40-, 14-, and 11-kDa core subunits). Mutations in single subunits exert different effects on the concentrations of their partner proteins. These may be summarized as follows: 1) No substantial loss in the 44- or 40-kDa core subunits is seen in single mutants; 2) the concentration of cytochrome c1 is also relatively unaffected by mutations in the other subunits except for the cytochrome b mutant which has 60% of the wild type level of cytochrome c1; 3) all the single mutants have only 15-20% of the normal amount of non-heme iron protein; 4) mutations in the non-heme iron protein have no appreciable effect on the concentrations of the other subunits; 5) mutations in single subunits cause parallel decreases in the concentrations of cytochrome b, the 14-, and the 11-kDa subunits. These results indicate that the synthesis or stability of a subset of subunits depends on the presence of other subunit polypeptides of the complex. At present we favor the idea that the observed changes in the concentrations of some subunits are due to higher turnover rates of the proteins in a partially assembled complex. Based on the mutant phenotypes, a tentative model for the assembly of coenzyme QH2-cytochrome c reductase is proposed. According to this model it is envisioned that the subunits interact with one another in the lipid bilayer. Maturation of apocytochrome b occurs after it is assembled with the nonstructural subunits to form a core structure. This intermediate complex interacts with the non-heme iron protein to form the active holoenzyme.     

The Nsp1p Carboxy-Terminal Domain Is Organized into Functionally Distinct Coiled-Coil Regions Required for Assembly of Nucleoporin Subcomplexes and Nucleocytoplasmic Transport

Nucleoporin Nsp1p, which has four predicted coiled-coil regions (coils 1 to 4) in the essential carboxy-terminal domain, is unique in that it is part of two distinct nuclear pore complex (NPC) subcomplexes, Nsp1p-Nup57p-Nup49p-Nic96p and Nsp1p-Nup82p-Nup159p. As shown by in vitro reconstitution, coiled-coil region 2 (residues 673 to 738) is sufficient to form heterotrimeric core complexes and can bind either Nup57p or Nup82p. Accordingly, interaction of Nup82p with Nsp1p coil 2 is competed by excess Nup57p. Strikingly, coil 3 and 4 mutants are still assembled into the core Nsp1p-Nup57p-Nup49p complex but no longer associate with Nic96p. Consistently, the Nsp1p-Nup57p-Nup49p core complex dissociates from the nuclear pores in nsp1 coil 3 and 4 mutant cells, and as a consequence, defects in nuclear protein import are observed. Finally, the nsp1-L640S temperature-sensitive mutation, which maps in coil 1, leads to a strong nuclear mRNA export defect. Thus, distinct coiled-coil regions within Nsp1p-C have separate functions that are related to the assembly of different NPC subcomplexes, nucleocytoplasmic transport, and incorporation into the nuclear pores.     

Evidence for electron equilibrium between the two hemes bL in the dimeric cytochrome bc1 complex

Structural analysis of the dimeric mitochondrial cytochrome bc1 complex suggests that electron transfer between inter-monomer hemes bL-bL may occur during bc1 catalysis. Such electron transfer may be facilitated by the aromatic pairs present between the two bL hemes in the two symmetry-related monomers. To test this hypothesis, R. sphaeroides mutants expressing His6-tagged bc1 complexes with mutations at three aromatic residues (Phe-195, Tyr-199, and Phe-203), located between two bL hemes, were generated and characterized. All three mutants grew photosynthetically at a rate comparable to that of wild-type cells. The bc1 complexes prepared from mutants F195A, Y199A, and F203A have, respectively, 78%, 100%, and 100% of ubiquinol-cytochrome c reductase activity found in the wild-type complex. Replacing the Phe-195 of cytochrome b with Tyr, His, or Trp results in mutant complexes (F195Y, F195H, or F195W) having the same ubiquinol-cytochrome c reductase activity as the wild-type. These results indicate that the aromatic group at position195 of cytochrome b is involved in electron transfer reactions of the bc1 complex. The rate of superoxide anion (O2*) generation, measured by the chemiluminescence of 2-methyl-6-(p-methoxyphenyl)-3,7-dihydroimidazo[1,2-alpha]pyrazin-3-one hydrochloride-O2* adduct during oxidation of ubiquinol, is 3 times higher in the F195A complex than in the wild-type or mutant complexes Y199A or F203A. This supports the idea that the interruption of electron transfer between the two bL hemes enhances electron leakage to oxygen and thus decreases the ubiquinol-cytochrome c reductase activity.     

Identification of residues in the carboxy-terminal domain of Clostridium perfringens alpha-toxin (phospholipase C) which are required for its biological activities

A panel of random mutants within the DNA encoding the carboxy-terminal domain of Clostridium perfringens alpha-toxin was constructed. Three mutants were identified which encoded alpha-toxin variants (Lys330Glu, Asp305Gly, and Asp293Ser) with reduced hemolytic activity. These variants also had diminished phospholipase C activity toward aggregated egg yolk phospholipid and reduced cytotoxic and myotoxic activities. Asp305Gly showed a significantly increased enzymatic activity toward the monodisperse substrate rhoNPPC, whereas Asp293Ser displayed a reduced activity toward this phospholipid analogue. In addition, Asp293Ser showed an increased dependence on calcium for enzymatic activity toward aggregated phospholipid and appeared calcium-depleted in PAGE band-shift assays. In contrast, neither Lys330Glu nor Asp305Gly showed altered dependence on calcium for enzymatic activity toward aggregated phospholipid. Asp305 is located in the interface between the amino- and carboxy-terminal domains, whereas Asp293 and Lys330 are surface exposed residues which may play a role in the recognition of membrane phospholipids.     

Mutations in the UQCC1-Interacting Protein,UQCC2, Cause Human Complex III Deficiency Associated with Perturbed Cytochrome b Protein Expression

Mitochondrial oxidative phosphorylation (OXPHOS) is responsible for generating the majority of cellular ATP. Complex III (ubiquinol-cytochrome c oxidoreductase) is the third of five OXPHOS complexes. Complex III assembly relies on the coordinated expression of the mitochondrial and nuclear genomes, with 10 subunits encoded by nuclear DNA and one by mitochondrial DNA (mtDNA). Complex III deficiency is a debilitating and often fatal disorder that can arise from mutations in complex III subunit genes or one of three known complex III assembly factors. The molecular cause for complex III deficiency in about half of cases, however, is unknown and there are likely many complex III assembly factors yet to be identified. Here, we used Massively Parallel Sequencing to identify a homozygous splicing mutation in the gene encoding Ubiquinol-Cytochrome c Reductase Complex Assembly Factor 2 (UQCC2) in a consanguineous Lebanese patient displaying complex III deficiency, severe intrauterine growth retardation, neonatal lactic acidosis and renal tubular dysfunction. We prove causality of the mutation via lentiviral correction studies in patient fibroblasts. Sequence-profile based orthology prediction shows UQCC2 is an ortholog of the Saccharomyces cerevisiae complex III assembly factor, Cbp6p, although its sequence has diverged substantially. Co-purification studies show that UQCC2 interacts with UQCC1, the predicted ortholog of the Cbp6p binding partner, Cbp3p. Fibroblasts from the patient with UQCC2 mutations have deficiency of UQCC1, while UQCC1-depleted cells have reduced levels of UQCC2 and complex III. We show that UQCC1 binds the newly synthesized mtDNA-encoded cytochrome b subunit of complex III and that UQCC2 patient fibroblasts have specific defects in the synthesis or stability of cytochrome b. This work reveals a new cause for complex III deficiency that can assist future patient diagnosis, and provides insight into human complex III assembly by establishing that UQCC1 and UQCC2 are complex III assembly factors participating in cytochrome b biogenesis.     

Molecular dissection of ø29 scaffolding protein function in an in vitro assembly system

An in vitro assembly system was developed to study prolate capsid assembly of phage ?29 biochemically, and to identify regions of scaffolding protein required for its functions. The crowding agent polyethylene glycol can induce bacteriophage ?29 monomeric capsid protein and dimeric scaffolding protein to co-assemble to form particles which have the same geometry as either prolate T=3 Q=5 procapsids formed in vivo or previously observed isometric particles. The formation of particles is a scaffolding-dependent reaction. The balance between the fidelity and efficiency of assembly is controlled by the concentration of crowding agent and temperature. The assembly process is salt sensitive, suggesting that the interactions between the scaffolding and coat proteins are electrostatic. Three N-terminal ?29 scaffolding protein deletion mutants, Delta 1-9, Delta 1-15 and Delta 1-22, abolish the assembly activity. Circular dichroism spectra indicate that these N-terminal deletions are accompanied by a loss of helicity. The inability of these proteins to dimerize suggests that the N-terminal region of the scaffolding protein contributes to the dimer interface and maintains the structural integrity of the dimeric protein. Two C-terminal scaffolding protein deletion mutants, Delta 79-97 and Delta 62-97, also fail to promote assembly. However, the secondary structure and the dimerization ability of these mutants are unchanged relative to wild-type, which suggests that the C terminus is the likely site of interaction with the capsid protein.     

The putative GTPase encoded by MTG3 functions in a novel pathway for regulating assembly of the small subunit of yeast mitochondrial ribosomes

Very little is known about biogenesis of mitochondrial ribosomes. The GTPases encoded by the nuclear MTG1 and MTG2 genes of Saccharomyces cerevisiae have been reported to play a role in assembly of the ribosomal 54 S subunit. In the present study biochemical screens of a collection of respiratory deficient yeast mutants have enabled us to identify a third gene essential for expression of mitochondrial ribosomes. This gene codes for a member of the YqeH family of GTPases, which we have named MTG3 in keeping with the earlier convention. Mutations in MTG3 cause the accumulation of the 15 S rRNA precursor, previously shown to have an 80-nucleotide 5' extension. Sucrose gradient sedimentation of mitochondrial ribosomes from temperature-sensitive mtg3 mutants grown at the permissive and restrictive temperatures, combined with immunobloting with subunit-specific antibodies, indicate that Mtg3p is required for assembly of the 30 S but not 54 S ribosomal subunit. The respiratory deficient growth phenotype of an mtg3 null mutant is partially rescued by overexpression of the Mrpl4p constituent located at the peptide exit site of the 54 S subunit. The rescue is accompanied by an increase in processed 15 S rRNA. This suggests that Mtg3p and Mrpl4p jointly regulate assembly of the small subunit by modulating processing of the 15 S rRNA precursor.     

Fast kinase domain-containing protein 3 is a mitochondrial protein essential for cellular respiration

Fas-activated serine/threonine phosphoprotein (FAST) is the founding member of the FAST kinase domain-containing protein (FASTKD) family that includes FASTKD1-5. FAST is a sensor of mitochondrial stress that modulates protein translation to promote the survival of cells exposed to adverse conditions. Mutations in FASTKD2 have been linked to a mitochondrial encephalomyopathy that is associated with reduced cytochrome c oxidase activity, an essential component of the mitochondrial electron transport chain. We have confirmed the mitochondrial localization of FASTKD2 and shown that all FASTKD family members are found in mitochondria. Although human and mouse FASTKD1-5 genes are expressed ubiquitously, some of them are most abundantly expressed in mitochondria-enriched tissues. We have found that RNA interference-mediated knockdown of FASTKD3 severely blunts basal and stress-induced mitochondrial oxygen consumption without disrupting the assembly of respiratory chain complexes. Tandem affinity purification reveals that FASTKD3 interacts with components of mitochondrial respiratory and translation machineries. Our results introduce FASTKD3 as an essential component of mitochondrial respiration that may modulate energy balance in cells exposed to adverse conditions by functionally coupling mitochondrial protein synthesis to respiration.     

Cross-linking and lipid efflux properties of apoA-I mutants suggest direct association between apoA-I helices and ABCA1

To explore the functional interactions between apoA-I and ABCA1, we correlated the cross-linking properties of several apoA-I mutants with their ability to promote cholesterol efflux. In a competitive cross-linking assay, amino-terminal deletion and double amino- and carboxy-terminal deletion mutants of apoA-I competed effectively the cross-linking of WT (125)I-apoA-I to ABCA1, while the carboxy-terminal deletion mutant apoA-I[Delta(220-243)] competed poorly. Direct cross-linking of WT apoA-I, amino-terminal, and double deletion mutants of apoA-I to ABCA1 showed similar apparent K(d) values (49-74 nM), whereas the apparent K(d) values of the carboxy-terminal deletion mutants apoA-I[Delta(185-243)] and apoA-I[Delta(220-243)] were increased 3-fold. Analysis of several internal deletions and point mutants of apoA-I showed that apoA-I[Delta(61-78)], apoA-I[Delta(89-99)], apoA-I[Delta(136-143)], apoA-I[Delta(144-165)], apoA-I[D102A/D103A], apoA-I[E125K/E128K/K133E/E139K], apoA-I[L141R], apoA-I[R160V/H162A], and WT apoA-I had similar ABCA1-mediated lipid efflux, and all competed efficiently the cross-linking of WT (125)I-apoA-I to ABCA1. WT apoA-I and ABCA1 could be cross-linked with a 3 A cross-linker. The WT apoA-I, amino, carboxy and double deletion mutants of apoA-I showed differences in the cross-linking to WT ABCA1 and the mutant ABCA1[W590S]. The findings are consistent with a direct association of different combinations of apoA-I helices with a complementary ABCA1 domain. Mutations that alter ABCA1/apoA-I association affect cholesterol efflux and inhibit biogenesis of HDL.     

Structure and function of the mitochondrial bc1 complex. A mutational analysis of the yeast Rieske iron-sulfur protein

Respiratory-defective mutants of Saccharomyces cerevisiae assigned to a single complementation group (G12) have been determined to have lesions in the iron-sulfur protein (Rieske protein) of ubiquinol: cytochrome c reductase. Mutants capable of expressing the protein were chosen for further studies. The genes from 13 independent isolates were cloned and their mutations sequenced. Twelve mutations were ascertained to cause single amino acid substitutions in the carboxyl-terminal regions of the protein between residues 127 and 173. This region is proposed to be part of the catalytic domain with the ligands responsible for co-ordinating the two irons of the 2Fe-2S cluster. Based on the catalytic properties of the ubiquinol: cytochrome c reductase complex and the electron paramagnetic resonance (e.p.r.) signals of the iron-sulfur protein, the mutants describe two different phenotypes. A subset of mutants have no detectable iron-sulfur cluster and are completely deficient in ubiquinol: cytochrome c reductase activity. These strains identify mutations in residues considered to be essential for binding of the iron or for maintaining a proper tertiary structure of the catalytic domain. A second group of mutants have reduced levels of enzymatic activity and exhibit e.p.r. spectra characteristic of the Rieske iron-sulfur cluster. The mutations in the latter strains have been ascribed to residues that influence the redox properties of the cluster by distorting the iron-binding pocket. A secondary and tertiary structure model is presented of the carboxyl-terminal 65 residues constituting the catalytic domain of the iron-sulfur protein. It is postulated that the two irons of the cluster are co-ordinated by three cysteine and a single histidine residue located in a loop structure. The catalytic domain also contains two short alpha-helices and three beta-strands that form a partial beta-barrel. Most of the hydrophilic amino acids are present in turns that map to one pole of the domain. When viewed in the context of the model, mutations that abolish the iron-sulfur cluster are mostly in residues defining the boundaries of the alpha-helices and beta-strands. The notable exception is a cysteine residue that has been assigned to the loop with the iron ligands. This cysteine residue is proposed to co-ordinate one iron of the cluster. Mutations that reduce ubiquinol: cytochrome c reductase activity and alter the redox potential of the cluster occur in residues located in the loop that contains the ligands of the cluster.