Biogenesis of mitochondria. Two-dimensional electrophoretic analysis of mitochondrial translation products in yeast

1. Mitochondrial translation products of yeast Saccharomyces cerevisiae were separated according to charge as well as molecular weight by a highly resolving two dimensional electorphoretic technique (isoelectric focusing in the first dimension ana SDS-electrophoresis in the second dimension). 2. The major protein components (the oligomeric form of subunit 9 of mitochondrial ATPase, var 1, cytochrome oxidase subunits I, II and III, subunit 6 of mitochondrial ATPase and cytochrome b apoprotein) were identified either from their mobility in SDS-electrophoresis or by using mit- mutants defective in certain mitochondrially made polypeptides. 3. This method allowed the separation of subunit III of cytochrome oxidase and subunit 6 of mitochondrial ATPase which cannot be resolved by conventional SDS-polyacrylamide gel electrophoresis. 4. Subunit II of cytochrome oxiodase resolves in two spots of similar pI values and subunit 6 of mitochondrial ATPase resolves in two spots of similar molecular weight. In both cases the double spots disappear simultaneously following a single mutation in the coresponding structural gene. 5. Total mitochondrial proteins were also resolved two-dimensionally revealing over 100 components. The mitochondrial translation products, with the exception of subunit 9 of mitochondrial ATPase, could be easily recognized among the other mitochondrial proteins.     

Isolation of the structural genes for the alpha and beta subunits of the mitochondrial ATPase from the fission yeast Schizosaccharomyces pombe

The structural genes for the two major subunits of the mitochondrial ATPase were isolated among genomic clones from the yeast Schizosaccharomyces pombe by transformation and complementation of mutants unable to grow on glycerol and lacking either the alpha or the beta subunits. The plasmid pMa1 containing a 2.3-kilobase genomic insert transformed the mutant A23-13 lacking a detectable alpha subunit. The transformant grew on glycerol and contained an alpha subunit of normal electrophoretic mobility. The plasmid pMa2 containing a 5.4-kilobase genomic insert transformed the mutant B59-1 lacking the beta subunit. The transformant grew on glycerol and contained a beta subunit of normal mobility. The structural gene for the beta ATPase subunit for the fission yeast S. pombe was localized within the pMa2 insert by hybridization to a probe containing the beta ATPase gene from the budding yeast Saccharomyces cerevisiae (Saltzgaber, J., Kunapuli, S., and Douglas, M. G. (1983) J. Biol. Chem. 258, 11465-11470). The mRNAs which hybridized to pMa1 and pMa2 were translated by a reticulocyte lysate into polypeptides of Mr = 59,000 and 54,000, respectively. These genes products reacted with an anti-F1-ATPase serum and therefore correspond most probably to precursors of the alpha and beta subunits.     

The role of subunit 4, a nuclear-encoded protein of the F0 sector of yeast mitochondrial ATP synthase, in the assembly of the whole complex

The yeast nuclear gene ATP4, encoding the ATP synthase subunit 4, was disrupted by insertion into the middle of it the selective marker URA3. Transformation of the Saccharomyces cerevisiae strain D273-10B/A/U produced a mutant unable to grow on glycerol medium. The ATP4 gene is unique since subunit 4 was not present in mutant mitochondria; the hypothetical truncated subunit 4 was never detected. ATPase was rendered oligomycin-insensitive and the F1 sector of this mutant appeared loosely bound to the membrane. Analysis of mitochondrially translated hydrophobic subunits of F0 revealed that subunits 8 and 9 were present, unlike subunit 6. This indicated a structural relationship between subunits 4 and 6 during biogenesis of F0. It therefore appears that subunit 4 (also called subunit b in beef heart and Escherichia coli ATP synthases) plays at least a structural role in the assembly of the whole complex. Disruption of the ATP4 gene also had a dramatic effect on the assembly of other mitochondrial complexes. Thus, the cytochrome oxidase activity of the mutant strain was about five times lower than that of the wild type. In addition, a high percentage of spontaneous rho- mutants was detected.     

Assembly of the mitochondrial membrane system. Characterization of nuclear mutants of Saccharomyces cerevisiae with defects in mitochondrial ATPase and respiratory enzymes.

Mutants of Saccharomyces cereviaiae showing defects in cytochrome oxidase, coenzyme QH2-cytochrome c reductase, and rutamycin-sensitive ATPase are described. The mutations have been established to be nuclear, based on complementation with a cytoplasmic petite tester strain and 2:2 segregation of tetrads. Genetic analysis indicate the coenzyme QH2-cytochrome c reductase and cytochrome oxidase mutants fall into 9 and 10 different complementation groups, respectively. The mutants also form distinct classes based on absorption spectra of the mitochondrial cytochromes. Two of the ATPase mutants lack detectable F1 ATPase, while the third synthesizes F1 but does not integrate it into a membrane complex. The latter mutant is missing one of the mitochondrially synthesized subunits of the rutamycin-sensitive ATPase complex.     

Identification of subunit I as the cytochrome b558 component of the cytochrome d terminal oxidase complex of Escherichia coli

The cytochrome d terminal oxidase complex was recently purified from Escherichia coli membranes (Miller, M. J., and Gennis , R. B. (1983) J. Biol. Chem. 258, 9159-1965). The complex contains two polypeptides, subunits I and II, as shown by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and three spectroscopically defined cytochromes, b558 , a1, and d. A mutant that failed to oxidize N,N,N',N'-tetramethyl-p-phenylenediamine was obtained which was lacking this terminal oxidase complex and was shown to map at a locus called cyd on the E. coli genome. In this paper, localized mutagenesis was used to generate a series of mutants in the cytochrome d terminal oxidase. These mutants were isolated by a newly developed selection procedure based on their sensitivity to azide. Two classes of mutants which map to the cyd locus were obtained, cydA and cydB . The cydA phenotype included the lack of all three spectroscopically detectable cytochromes as well as the absence of both polypeptides, determined by immunological criteria. Strains manifesting the cydB phenotype lacked cytochromes a1 and d, but had a normal amount of cytochrome b558 . Immunological analysis showed that subunit I (57,000 daltons) was present in the membranes, but that subunit II (43,000 daltons) was missing. These data justify the conclusion that subunit I of this two-subunit complex can be identified as the cytochrome b558 component of the cytochrome d terminal oxidase complex.     

Conformational interactions between alpha and beta subunits in the F1 ATPase of Escherichia coli as shown by chemical modification of uncA401 and uncD412 mutant enzymes

In contrast to wild-type F1 adenosine triphosphatase, the beta subunits of soluble ATPase from Escherichia coli mutant strains AN120 (uncA401) and AN939 (uncD412) were not labeled by the fluorescent thiol-specific reagents 5-iodoacetamidofluorescein, 2-(4'-iodoacetamidoanilino)naphthalene-6-sulfonic acid or 4-[N-(iodoacetoxy)ethyl-N-methyl]amino-7-nitrobenzo-2-oxa-1,3-diazole. The mutation in the alpha subunit (uncA401) of F1 ATPase thus influences the accessibility of the single cysteinyl residue in the beta subunit. Following reaction of ATPase with 4-chloro-7-nitrobenzo-2-oxa-1,3-diazole or N,N'-dicyclohexylcarbodiimide, the alpha and beta subunits of the uncA401, but not of the uncD412 mutant F1 ATPase were intensely labeled by a fluorescent thiol reagent. The mutation in the beta subunit (uncD412) thus influences the accessibility of the cysteinyl residues in the alpha subunit. In other work [Stan-Lotter, H. and Bragg, P.D. (1986) Arch. Biochem. Biophys. 248] we have shown that 4-chloro-7-nitrobenzo-2-oxa-1,3-diazole and 2-(4'-iodoacetamidoanilino)naphthalene-6-sulfonic acid react with a different beta subunit from that labeled by N,N'-dicyclohexylcarbodiimide. This asymmetry with respect to modification by 4-chloro-7-nitrobenzo-2-oxa-1,3-diazole and N,N'-dicyclohexylcarbodiimide was seen in both mutant enzymes. In addition, the modification of one beta subunit of the uncA401 F1 ATPase induced the previously unreactive sulfhydryl group of another beta subunit to react with 2-(4'-iodoacetamidoanilino-naphthalene-6-sulfonic acid. These results provide evidence for at least three types of conformational interactions of the major subunits of F1 ATPase: from alpha to beta, from beta to alpha, and from beta to beta. As in wild-type ATPase, labeling of membrane-bound unc mutant ATPase by a fluorescent thiol reagent modified the alpha subunits. This suggests that a conformational change of yet a different type occurs when the enzyme binds to the membrane.     

Failure to assemble the alpha 3 beta 3 subcomplex of the ATP synthase leads to accumulation of the alpha and beta subunits within inclusion bodies and the loss of mitochondrial cristae in Saccharomyces cerevisiae

The F(1) component of mitochondrial ATP synthase is an oligomeric assembly of five different subunits, alpha, beta, gamma, delta, and epsilon. In terms of mass, the bulk of the structure ( approximately 90%) is provided by the alpha and beta subunits, which form an (alphabeta)(3) hexamer with adenine nucleotide binding sites at the alpha/beta interfaces. We report here ultrastructural and immunocytochemical analyses of yeast mutants that are unable to form the alpha(3)beta(3) oligomer, either because the alpha or the beta subunit is missing or because the cells are deficient for proteins that mediate F assembly (e.g. Atp11p, Atp12p, or Fmc1p). The F(1) alpha(1) and beta subunits of such mutant strains are detected within large electron-dense particles in the mitochondrial matrix. The composition of the aggregated species is principally full-length F(1) alpha and/or beta subunit protein that has been processed to remove the amino-terminal targeting peptide. To our knowledge this is the first demonstration of mitochondrial inclusion bodies that are formed largely of one particular protein species. We also show that yeast mutants lacking the alpha(3)beta(3) oligomer are devoid of mitochondrial cristae and are severely deficient for respiratory complexes III and IV. These observations are in accord with other studies in the literature that have pointed to a central role for the ATP synthase in biogenesis of the mitochondrial inner membrane.     

The mitochondrial F1ATPase alpha-subunit is necessary for efficient import of mitochondrial precursors.

The mitochondrial import and assembly of the F1ATPase subunits requires, respectively, the participation of the molecular chaperones hsp70SSA1 and hsp70SSC1 and other components operating on opposite sides of the mitochondrial membrane. In previous studies, both the homology and the assembly properties of the F1ATPase alpha-subunit (ATP1p) compared to the groEL homologue, hsp60, have led to the proposal that this subunit could exhibit chaperone-like activity. In this report the extent to which this subunit participates in protein transport has been determined by comparing import into mitochondria that lack the F1ATPase alpha-subunit (delta ATP1) versus mitochondria that lack the other major catalytic subunit, the F1ATPase beta-subunit (delta ATP2). Yeast mutants lacking the alpha-subunit but not the beta-subunit grow much more slowly than expected on fermentable carbon sources and exhibit delayed kinetics of protein import for several mitochondrial precursors such as the F1 beta subunit, hsp60MIF4 and subunits 4 and 5 of the cytochrome oxidase. In vitro and in vivo the F1 beta-subunit precursor accumulates as a translocation intermediate in absence of the F1 alpha-subunit. In the absence of both the ATPase subunits yeast grows at the same rate as a strain lacking only the beta-subunit, and import of mitochondrial precursors is restored to that of wild type. These data indicate that the F1 alpha-subunit likely functions as an "assembly partner" to influence protein import rather than functioning directly as a chaperone. These data are discussed in light of the relationship between the import and assembly of proteins in mitochondria.     

Recent developments on structural and functional aspects of the F1 sector of H+-linked ATPases

This review concerns the catalytic sector of F1 factor of the H+-dependent ATPases in mitochondria (MF1), bacteria (BF1) and chloroplasts (CF1). The three types of F1 have many similarities with respect to the structural parameters, subunit composition and catalytic mechanism. An alpha 3 beta 3 gamma delta epsilon stoichiometry is now accepted for MF1 and BF1; the alpha 2 beta 2 gamma 2 delta 2 epsilon 2 stoichiometry for CF1 remains as matter of debate. The major subunits alpha, beta and gamma are equivalent in MF1, BF1 and CF1; this is not the case for the minor subunits delta and epsilon. The delta subunit of MF1 corresponds to the epsilon subunit of BF1 and CF1, whereas the mitochondrial subunit equivalent to the delta subunit of BF1 and CF1 is probably the oligomycin sensitivity conferring protein (OSCP). The alpha beta gamma assembly is endowed with ATPase activity, beta being considered as the catalytic subunit and gamma as a proton gate. On the other hand, the delta and epsilon subunits of BF1 and CF1 most probably act as links between the F1 and F0 sectors of the ATPase complex. The natural mitochondrial ATPase inhibitor, which is a separate protein loosely attached to MF1, could have its counterpart in the epsilon subunit of BF1 and CF1. The generally accepted view that the catalytic subunit in the different F1 species is beta comes from a number of approaches, including chemical modification, specific photolabeling and, in the case of BF1, use of mutants. The alpha subunit also plays a central role in catalysis, since structural alteration of alpha by chemical modification or mutation results in loss of activity of the whole molecule of F1. The notion that the proton motive force generated by respiration is required for conformational changes of the F1 sector of the H+-ATPase complex has gained acceptance. During the course of ATP synthesis, conversion of bound ADP and Pi into bound ATP probably requires little energy input; only the release of the F1-bound ATP would consume energy. ADP and Pi most likely bind at one catalytic site of F1, while ATP is released at another site. This mechanism, which underlines the alternating cooperativity of subunits in F1, is supported by kinetic data and also by the demonstration of partial site reactivity in inactivation experiments performed with selective chemical modifiers. One obvious advantage of the alternating site mechanism is that the released ATP cannot bind to its original site.(ABSTRACT TRUNCATED AT 400 WORDS)     

Role of exogenous hemin in the synthesis of hemoproteins and nonheme proteins during glucose repression in Saccharomyces cerevisiae

Exogenous addition of hemin to glucose-repressed cells of Saccharomyces cerevisiae stimulates the incorporation of amino acid into cytoplasmic proteins twofold. There was no significant change in the synthesis of total cytoplasmic RNA whereas a 40% increase in the synthesis of poly(A)-containing RNA was observed upon hemin treatment. Cell-free translation of cytoplasmic mRNAs and immunoprecipitation analysis of the translated products with antibodies against subunit V of cytochrome oxidase and the alpha and beta subunits of F1-ATPase reveals that there is an eightfold enrichment of the mRNA for subunit V of cytochrome oxidase upon hemin treatment. The effect of hemin on the alpha and beta subunits of F1-ATPase is only marginal, suggesting a differential role for heme in the synthesis of hemoproteins and nonheme proteins during glucose repression.     

Deletion of the COX7 gene in Saccharomyces cerevisiae reveals a role for cytochrome c oxidase subunit VII In assembly of remaining subunits

Cytochrome c oxidase from Saccharomyces cerevisiae is composed of nine subunits. Subunits I, II and III are products of mitochondrial genes, while subunits IV, V, VI, VII, VIIa and VIII are products of nuclear genes. To investigate the role of cytochrome c oxidase subunit VII in biogenesis or functioning of the active enzyme complex, a null mutation in the COX7 gene, which encodes subunit VII, was generated, and the resulting cox7 mutant strain was characterized. The strain lacked cytochrome c oxidase activity and haem a/a3 spectra. The strain also lacked subunit VII, which should not be synthesized owing to the nature of the cox7 mutation generated in this strain. The amounts of remaining cytochrome c oxidase subunits in the cox7 mutant were examined. Accumulation of subunit I, which is the product of the mitochondrial COX1 gene, was found to be decreased relative to other mitochondrial translation products. Results of pulse-chase analysis of mitochondrial translation products are consistent with either a decreased rate of translation of COX1 mRNA or a very rapid rate of degradation of nascent subunit I. The synthesis, stability or mitochondrial localization of the remaining nuclear-encoded cytochrome c oxidase subunits were not substantially affected by the absence of subunit VII. To investigate whether assembly of any of the remaining cytochrome c oxidase subunits is impaired in the mutant strain, the association of the mitochondrial-encoded subunits I, II and III with the nuclear-encoded subunit IV was investigated.(ABSTRACT TRUNCATED AT 250 WORDS)     

Purification and characterization of the F1 ATPase from Bacillus subtilis and its uncoupler-resistant mutant derivatives.

The F1 ATPase of Bacillus subtilis BD99 was extracted from everted membrane vesicles by low-ionic-strength treatment and purified by DEAE-cellulose chromatography, hydrophobic interaction chromatography, and anion-exchange high-performance liquid chromatography. The subunit structure of the enzyme was examined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis in the absence and presence of urea. In the absence of urea, the alpha and beta subunits comigrated and the ATPase was resolved into four bands. The mobility of the beta subunit, identified by immunoblotting with anti-beta from Escherichia coli F1, was altered dramatically by the presence of urea, causing it to migrate more slowly than the alpha subunit. The catalytic activity of the ATPase was strongly metal dependent; in the absence of effectors, the Ca2+-ATPase activity was 15- to 20-fold higher than the Mg2+ -ATPase activity. On the other hand, sulfite anion, methanol, and optimally, octylglucoside stimulated the Mg2+ -ATPase activity up to twice the level of Ca2+ -ATPase activity (specific activity, about 80 mumol of Pi per min per mg of protein). The F1 ATPase was also isolated from mutants of B. subtilis that had been isolated and characterized in this laboratory by their ability to grow in the presence of protonophores. The specific activities of the ATPase preparations from the mutant and the wild type were very similar for both Mg2+- and Ca2+ -dependent activities. Kinetic parameters (Vmax and Km for Mg-ATP) for octylglucoside-stimulated Mg2+ -ATPase activity were similar in both preparations. Structural analysis by polyacrylamide gel electrophoresis and isoelectric focusing indicated that the five F1 subunits from ATPase preparations from the mutant and wild-type strains had identical apparent molecular weights and that no charge differences were detectable in the alpha and beta subunits in the two preparations. Thus, the increased ATPase activity that had been observed in the uncoupler-resistant mutants is probably not due to a mutation in the F1 moiety of the ATPase complex.     

Nuclear mutants of Neurospora crassa temperature-sensitive for the synthesis of cytochrome aa3. Mitochondrial protein synthesis and analysis of the polypeptide composition of cytochrome c oxidase.

Three previously isolated mutants of Neurospora crassa, temperature-sensitive for the production of cytochrome aa3, have been further analyzed. These mutants have a slightly reduced capacity for mitochondrial protein synthesis when grown at 41 degrees C, although this relative deficiency appeared to be no greater than the deficiency in other cytochrome-aa3-deficient mutants. Thermolability studies revealed that the cytochrome c oxidase purified from each of the mutants grown at 23 degrees C is no more sensitive to heat inactivation than the enzyme isolated from wild-type cells. Sodium dodecylsulfate gel electrophoresis of immunoprecipitates obtained from the mitochondria of each of the mutants grown at 23 degrees C, using antiserum directed against holocytochrome c oxidase, indicated that all the subunits of cytochrome c oxidase were present in relative amounts similar to those found in mitochondria from wild-type cultures. However, when the mitochondria from mutant cultures grown at 41 degrees C were examined in the above fashion, only subunits 5 and 6 of the oxidase were detected. Nonetheless, the mitochondrially synthesized subunit 1, 2 and 3 polypeptides could be immunoprecipitated from mitochondria isolated from mutant cells grown at 41 degrees C and labelled with [3H]leucine in medium containing cycloheximide. Although subunits 4 and 7 could not be detected, because a suitable antibody was not available, the fact that five of the seven subunits were present, but not associated with each other, suggested that the genetic defects in these mutants may affect the process of cytochrome c oxidase assembly.     

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.     

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

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

Identification of mitochondrial proteins in membrane preparations from Chlamydomonas reinhardtii.

Preparations enriched in Chlamydomonas reinhardtii thylakoids have proven useful in the study of photosynthesis. Many of their polypeptides however remain unidentified. We report here on three of those, h1 (34 kDa), h2 (11 kDa), and P3 (63 kDa). h1, h2, and P3 are present in all tested mutants of C. reinhardtii lacking either one or several of the photosynthetic chain complexes or depleted in thylakoid membranes. h2 is an ascorbate-reducible, soluble c550-type cytochrome encoded in the nucleus. It cross-reacts immunologically with mitochondrial cytochromes c from various sources and contains a hexapeptide encoded in C. reinhardtii cytochrome c cDNA. P3, a nuclear-encoded peripheral protein, cross-reacts with various ATP synthase beta subunits. Its N-terminal sequence is encoded in C. reinhardtii mitochondrial beta subunit cDNA. h1 behaves as an integral hemoprotein; it is absent in a mitochondrial mutant that carries a deletion in apocytochrome b gene. We conclude that C. reinhardtii mitochondrial membranes copurify with thylakoid membranes. h1 is part of the cytochrome bc1 complex, h2 is cytochrome c, and P3 is the beta subunit of mitochondrial ATP synthase.     

A nuclear mutation conferring aurovertin resistance to yeast mitochondrial adenosine triphosphatase.

A single gene nuclear yeast mutant was isolated whose mitochondrial F1-ATPase was resistant to the specific F1 inhibitor aurovertin. The mutant enzyme was not cross-resistant to other F1 inhibitors. The binding of aurovertin to F1 and to the two largest F1 subunits (alpha and beta) was measured by enhancement of aurovertin fluorescence. Aurovertin bound to wild type F1-ATPase and to its monomeric beta subunit with about the same binding constant. It failed to bind to wild type alpha subunit or to either F1 or F1 subunits from the mutant. The aurovertin-resistant mutant thus contains an altered nuclear gene which specifies the structure of the beta subunit of F1.