Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:1.9.3.1 (cytochrome oxidase)
 8,822 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Six chloroplast gene mutants of Chlamydomonas reinhardtii resistant to spectinomycin, erythromycin, or streptomycin have been assessed for antibiotic resistance of their chloroplast ribosomes. Four of these mutations clearly confer high levels of antibiotic resistance on the chloroplast ribosomes both in vivo. Although one mutant resistant to streptomycin and one resistant to spectinomycin have chloroplast ribosomes as sensitive to antibiotics as those of wild type in vivo, these mutations can be shown to alter the wildtype sensitivity of chloroplast ribosomes in polynucleotide-directed amino acid incorporation in vitro. Genetic analysis of these six chloroplast mutants and three similar mutants (Sager, 1972), two of which have been shown to affect chloroplast ribosomes (Mets and Bogorad, 1972; Schlanger and Sager, 1974), indicates that in Chlamydomonas at least three chloroplast gene loci can affect streptomycin resistance of chloroplast ribosomes and that two can affect erythromycin resistance. The three spectinomycin-resistant mutants examined appear to be alleles at a single chloroplast gene locus, but may represent mutations at two different sites within the same gene. Unlike wild type, the streptomycin and spectinomycin resistant mutants which have chloroplast ribosomes sensitive to antibiotics in vivo, grow well in the presence of antibiotic by respiring exogenously supplied acetate as a carbon source, and have normal levels of cytochrome oxidase activity and cyanide-sensitive respiration. We conclude that mitochondrial protein synthesis in these mutants is resistant to these antibiotics, whereas in wild type it is sensitive. To explain the behavior of these two chloroplast gene mutants as well as other one-step mutants which are resistant both photosynthetically and when respiring acetate in the dark, we have postulated that a mutation in a single chloroplast gene may result in alteration of both chloroplast and mitochondrial ribosomes. Mitochondrial resistance would appear to be the minimal necessary condition for survival of all such mutants, and antibiotic-resistant chloroplast ribosomes would be necessary for survival only under photosynthetic conditions.
Mol Gen Genet 1975 Oct 03
PMID:Chloroplast genes in Chlamydomonas affecting organelle ribosomes. Genetic and biochemical analysis of analysis of antibiotic-resistant mutants at several gene loci. 12 89

We have previously isolated six non-allelic, nuclear mutations (sui loci) that partially suppress the growth, respiratory and cytochrome abnormalities of the extranuclear [poky] mutant. A comparison of the mitochondrial ribosome profiles of suppressed and unsuppressed [poky] strains revealed that five of the six suppressors alleviate at least partially the deficiency of mitochondrial small ribosomal subunits that is associated with the [poky] genotype. Six independently isolated Group 1 extranuclear mutants, namely [exn-1], [exn-2], [exn-4-a1, [stp-b1], [SG-1] and [SG-3-A1, which have growth and cytochrome phenotypes similar to [poky] also were found to be deficient in small subunits of mitochondrial ribosomes. Using cytochrome aa3 and b production as a criterion for mitochondrial protein synthesis, it could be shown that the nuclear su I suppressors of [poky] also suppress the other six Group I extranuclear mutants. However, differences in the efficiencies of suppression by suI suppressors suggest that at least some of Group I extrachromosomal mutants are not simply re-isolates of [poky], but represent distinct extranuclear mutations.
Mol Gen Genet 1978 May 31
PMID:Nuclear suppressors of the [poky] cytoplasmic mutant in Neurospora crassa. III. Effects on other cytoplasmic mutants and on mitochondrial ribosome assembly in [poky]. 14 10

There is a major reduction in respiratory competence, and inhibitionof growth, several hours after the addition of erythromycin or chloramphenicol to Saccharomyces cerevisiae growing in medium containing a non-fermentable carbon source. Spectrographic evidence is presented for a loss of cytochrome oxidase as a consequence of the antibiotic treatment. This loss is prevented by cyanide or oligomycin. When glucose is added, however, the loss occurs irrespective of the presence of the respiratory inhibitors. Cycloheximide does not affect respiratory competence or cause loss of cytochrome oxidase, and it prevents the loss elicited by erythromycin if both compounds are added together. However, if cycloheximide is added some time after the addition of erythromycin, it fails to block the response to the latter drug. The results cannot be accounted for on the basis of the segregation of a finite number of mitochondria into an increasing number of progeny cells but, rather, suggest that the mitochondria are modified during growth in chloramphenicol or erythromycin.
J Gen Microbiol 1975 Nov
PMID:Loss of cytochrome oxidase in Saccharomyces cerevisiae during inhibition of mitochondrial protein synthesis by erythromycin and chloramphenicol. 17 2

Nineteen mutants of S. cerevisiae exhibiting a double deficiency in cytochrome oxidase and coenzyme QH2-cytochrome c reductase (also cytochrome b deficient) have been studied. The mutants have been crossed to a set of rho- tester strains with different segments of mitochondrial DNA. The mutants have also been crossed to mit- testers with defined genetic lesions. In addition, crosses were performed with a respiratory competent strain to ascertain whether mitotic and meiotic segregants could be isolated with only one of the two enzymatic deficiencies. The rho- testers allowed the doubly deficient mutants to be separated into two classes. Mutants in class 1 were not restored by any of the rho- testers and appeared to have separate mutations, one in cytochrome oxidase and the other in cytochrome b. Mutants in class 2 were restored by a set of rho- clones whose retained segments of mitochondrial DNA contained the cytochrome b but not the cytochrome oxidase loci. These appeared to behave as single hit mutations. Further studies, however, indicated that both class 1 and class 2 mutants carried separate mutations in two different loci. Mitotic and meiotic segregants with a single enzymatic deficiency could be isolated. In a number of strains, the mutations were mapped in known cytochrome oxidase and cytochrome b loci. The apparent discrepancy of the rho- tests for the class 2 mutants was shown to be probably due to a high unstability in one of the mutations. It has been concluded that all the doubly deficient strains carry two mutations in previously described cytochrome oxidase and cytochrome b loci. This conclusion argues against the existence of a single gene on mitochondrial DNA that controls the biosynthesis of the two respiratory enzymes.
Mol Gen Genet 1976 Nov 24
PMID:Assembly of the mitochondrial membrane system. XIX. Genetic characterization of mit- mutants with deficiencies in cytochrome oxidase and coenzyme qh2-cytochrome c reductase. 18 77

Glucose represses mitochondrial biogenesis and the fermentation of maltose, galactose and sucrose in yeast. We have analyzed the effect of D-glucosamine on these functions in order to determine if it can produce a similar repression. It was found that glucosamine represses the respiration rate (QO2) but more rapidly than glucose and to a final level slightly higher than in glucose-treated cells. Derepression of the respiration rate following either glucose or glucosamine repression was similar. A two hour lag was followed by a linear increase in QO2 to the derepressed level. Both glucose and glucosamine repressed the level of cytochrome oxidase to the same level. Glucosamine was also found to repress maltose and galactose fermentation but not sucrose fermentation. The derepression of maltase synthesis was inhibited by glucosamine. The constitutive synthesis of maltase was repressed by the addition of glucosamine. Glucosamine was judged to produce a repressed state similar to glucose repression in many respects.
Mol Gen Genet 1977 Oct 24
PMID:An evaluation of D-glucosamine as a gratuitous catabolite repressor of Saccharomyces carlsbergensis. 20 60

A set of mitochondrial antibiotic-resistant mutants of Paramecium have been analyzed with respect to their growth-rates, cytochromic content and respiratory properties. The mutants could be arranged in a continuous series ranging from strains equivalent to wild-type to severely affected ones; affected strains display longer generation times, reduced amount of cytochrome oxidase and very high levels of cyanideinsensitive respiration. Perfect phenocopies of the mutants were obtained by treating wild-type cells with low concentrations of erythromycin suggesting that the mutations exert their pleiotropic effect by perturbating mitochondria protein synthesis in agreement with the idea that these mutations affect the mitochondrial ribosomes. In the mitochondria of some of the mutants, electrons can be channelled with equal efficiency into the "classical" cyanide-sensitive pathway and the alternate cyanide insensitive (and SHAM-sensitive) one, providing direct demonstration of the branching of these two respiratory pathways. In the absence of any added inhibitor, however, electrons tend to be channelled in the cyanide-sensitive pathway. All the physiological data fit perfectly the genetic data concerning the "stability" of the various mutations in "mixed mitochondrial populations", i.e., markers that were known to be strongly counter-selected with respect to wild-type in such populations correspond to severely affected strains, while markers that were known to be "stable" correspond to "healthy" strains. A more quantitative analysis of the data shows that that there is little or no "complementation" between wild-type and mutated mitochondria in mixed cells indicating a high extent of functional autonomy of mitochondria in Paramecium.
Mol Gen Genet 1978 May 03
PMID:Physiological consequences of mitochondrial antibiotic-resistant mutations in Paramecium: growth-rates, cytochromic defects and cyanide-insensitive respiration of mutant and erythromycin-treated wild-type strains. 20 5

The mitochondria of the cyt-2-1, cya-3-16, cya-4-23 and 299-1 nuclear mutants and the [mi-3] and [exn-5] cytoplasmic mutants of Neurospora crassa are deficient in cytochrome aa3, while the cyb-1-1 and cyb-2-1 mutants have mitochondrial b-cytochrome deficiencies. However, the mitochondria from cyb-1-1 cyt-2-1, cyb-1-1 [mi-3] and cyb-2-1 [mi-3] double mutants contain 30% to 50% of the amount of cytochrome aa3 that is present in mitochondria from wild-type; i.e. cyb-1-1 and cyb-2-2 act as suppressors of the cytochrome aa3 deficiency phenotypes that are associated with cyt-2-1 and [mi-3] mutations. The production of cytochrome aa3 can be induced in cyt-2-1 and [mi-3] by growing cells in medium containing antimycin A, an inhibitor of electron transport in the cytochrome bc1 segment of the mitochondrial electrontransport chain. Moreover, the growth of the [mi-3] mutant is strongly stimulated by low concentrations of antimycin A. The induction of cytochrome aa3 by antimycin treatments does not occur in [exn-5], cya-4-23 and 299-1 cells; but does take place in cya-3-16 cells. Although some of the seven constituent polypeptides of cytochrome aa3 are present in mitochondria of [mi-3], the holoenzyme complex is not formed in the mutant. In contrast, the mitochondria of cyb-1-1 [mi-3] and cyb-2-2 [mi-3] double mutants contain a fully assembled cytochrome oxidase complex as well as some unassembled subunit polypeptides. The observations are indicative of the existence of at least two regulatory systems controlling the production of cytochrome aa3. One of the circuits appears to control the basal or "constitutive" production of cytochrome oxidase, the other seems to coordinate the level of cytochrome aa3 with some function of the mitochondrial cytochrome bc1 complex, possibly electron transport.
Mol Gen Genet 1978 Oct 25
PMID:A regulatory system controlling the production of cytochrome aa3 in Neurospora crassa. 21 99

Three nuclear mutants of Neurospora crassa, temperature-sensitive for the synthesis of cytochrome aa3 have been isolated. When grown at 41 degrees C the mutants have large amounts of KCN-insensitive respiration, reduced amounts of cytochrome aa3 and cytochrome c oxidase activity, and grow more slowly than wild-type cultures grown at the same temperature. When the mutants are grown at 23 degrees C, they are virtually indistinguishable from wild-type strains. The mutants were selected on the basis of their slow growth at 41 degrees C in medium containing salicylhydroxamic acid, and by their inability to reduce 2,3,5-triphenyltetrazolium chloride at 41 degrees c. The selecttion technique was designed to eliminate mutants that did not carry thermolabile electron transport chain components. However, studies on the thermolability of the cytochrome oxidase activity in isolated mitochondria indicate that the enzyme of the mutants is no more susceptible to heat denaturation than is the enzyme in wild-type mitochondria. This suggests that the synthesis or assembly of cytochrome aa3 may be altered in the mutants at the restrictive temperature.
Mol Gen Genet 1978 Oct 25
PMID:Nuclear mutants of Neurospora crassa temperature-sensitive for the synthesis of cytochrome aa3. I. Isolation and preliminary characterization. 21

Fifty eight mitochondrial mutants (p + mit- mutants), all deficient in cytochrome oxidase activity and previously assigned to the genetic region oxi3 on the mitochondrial DNA, were mapped by the method of "petite deletion mapping". This procedure resulted in the identification of at least twenty one different classes of oxi3 mutants, which could be arranged in a linear order. Moreover, it provided a set of twenty three p- petite mutants, each containing a differentially deleted mit DNA segment included in the oxi3 region. The two sets of mutants, p+ oxi3- and p- oxi3+, will be of interest for a further genetic and physical analysis of this mitochondrial DNA segment which spans over about ten thousand base pairs and controls the subunit I of cytochrome oxidase.
Mol Gen Genet 1979 Jan 02
PMID:Petite deletion map of the mitochondrial oxi3 region in Saccharomyces cerevisiae. 21 2

During germination, Streptomyces antibioticus arthrospores passed through stages: darkening, swelling and germ tube emergence. The first stage, darkening, whose main features were a decrease in absorbance and a loss of refractility, only required exogenous divalent cations (Ca2+, Mg2+ or Fe2+) and energy that can be obtained from the spore reserves. This stage was blocked by agents that inhibit ATP formation but not by antibiotics that inhibit macromolecular synthesis. The second stage, swelling, needed an exogenous carbon source and was not blocked by mitomycin C. In this stage, the spores exhibited the highest cytochrome oxidase and catalase activities and respiratory quotient. The last stage, germ tube emergence, required additional carbon and nitrogen sources. Ammonium compounds were superior to nitrate. Dry weight remained constant during the stages of darkening and swelling, with a rapid increase from the moment of germ tube emergence. Optimum pH and temperature for germination were 8.0 and 45 degrees C, respectively. Heat treatment (55 degrees C for 10 min) had no effect on germination. The fine structure of the spore underwent important changes during germination. The wall of the swollen spore became stratified and the inner layer was continuous with the germ tube wall. Macromolecular synthesis occurred in the sequence RNA, protein and then DNA. Rifampicin, streptomycin and mitomycin C prevented synthesis when added at the start of incubation. The same effect was obtained if the addition was made during germination, except with mitomycin C which inhibited DNA, but not RNA and protein synthesis.
J Gen Microbiol 1978 Apr
PMID:Fine structure, physiology and biochemistry of arthrospore germination in Streptomyces antibioticus. 34 27


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