Mutations affecting the mitochondrial genes encoding the cytochrome oxidase subunit I and apocytochrome b of Chlamydomonas reinhardtii

Mitochondrial mutants of the green alga Chlamydomonas reinhardtii that are inactivated in the cytochrome pathway of respiration have previously been isolated. Despite the fact that the alternative oxidase pathway is still active the mutants have lost the capacity to grow heterotrophically (dark + acetate) and display reduced growth under mixotrophic conditions (light + acetate). In crosses between wild-type and mutant cells, the meiotic progeny only inherit the character transmitted by the mt ^– parent, which indicates that the mutations are located in the 15.8 kb linear mitochondrial genome. Two new mutants (dum-18 and dum-19) have now been isolated and characterized genetically, biochemically and at the molecular level. In addition, two previously isolated mutants (dum-11 and dum-15) were characterized in more detail. dum-11 contains two types of deleted mitochondrial DNA molecules: 15.1 kb monomers lacking the subterminal part of the genome, downstream of codon 147 of the apocytochrome b (COB) gene, and dimers resulting from head-to-head fusion of asymmetrically deleted monomers (15.1 and 9.5 kb DNA molecules, respectively). As in the wild type, the three other mutants contain only 15.8 kb mitochondrial DNA molecules. dum-15 is mutated at codon 140 of the COB gene, a serine (TCT) being changed into a tyrosine (TAC). dum-18 and dum-19 both inactivate cytochrome c oxidase, as a result of frameshift mutations (addition or deletion of 1 bp) at codons 145 and 152, respectively, of the COX1 gene encoding subunit I of cytochrome c oxidase. In a total of ten respiratory deficient mitochondrial mutants characterized thus far, only mutations located in COB or COXI have been isolated. The possibility that the inactivation of the other mitochondrial genes is lethal for the cells is discussed.     

Biochemical,genetic and molecular characterization of new respiratory-deficient mutants inChlamydomonas reinhardtii

Eight respiratory-deficient mutants ofChlamydomonas reinhardtii have been isolated after mutagenic treatment with acriflavine or ethidium bromide. They are characterized by their inability to grow or their very reduced growth under heterotrophic conditions. One mutation (Class III) is of nuclear origin whereas the seven remaining mutants (Classes I and II) display a predominantly paternalmt ^- inheritance, typical of mutations residing in the mitochondrial DNA. Biochemical analysis has shown that all mutants are deficient in the cyanide-sensitive cytochrome pathway of the respiration whereas the alternative pathway is still functional. Measurements of complexes II + III (antimycin-sensitive succinate-cytochromec oxido-reductase) and complex IV (cytochromec oxidase) activities allowed to conclude that six mutations have to be localized in the mitochondrial apocytochromeb (COB) gene, one in the mitochondrial cytochrome oxidase subunit I (COI) gene and one in a nuclear gene encoding a component of the cytochrome oxidase complex. By using specific probes, we have moreover demonstrated that five mutants (Class II mutants) contain mitochondrial DNA molecules deleted in the terminal end containing the COB gene and the telomeric region; they also possess dimeric molecules resulting from end-to-end junctions of deleted monomers. The two other mitochondrial mutants (Class I) have no detectable gross alteration. Class I and Class II mutants can also be distinguished by the pattern of transmission of the mutation in crosses.Anin vivo staining test has been developed to identify rapidly the mutants impaired in cyanide-sensitive respiration.     

Genetic mapping of mitochondrial markers by recombinational analysis in Chlamydomonas reinhardtii

The mitochondrial genome of Chlamydomonas reinhardtii is a 15.8 kb linear DNA molecule present in multiple copies. In crosses, the meiotic products only inherit the mitochondrial genome of the mating type minus (paternal) parent. In contrast mitotic zygotes transmit maternal and paternal mitochondrial DNA copies to their diploid progeny and recombinational events between molecules of both origins frequently occur. Six mitochondrial mutants unable to grow in the dark (dk^? mutants) were crossed in various combinations and the percentages of wild-type dk⁺ recombinants were determined in mitotic zygotes when all progeny cells had become homoplasmic for the mitochondrial genome. In crosses between strains mutated in the COB (apocytochrome ) gene and strains mutated in the COX1 (subunit 1 of cytochrome oxidase) gene, the frequency of recombination was 13.7% (± 3.2%). The corresponding physical distance between the mutation sites was 4.3 kb. In crosses between strains carrying mutations separated by about 20 bp, a recombinational frequency of 0.04% (± 0.02%) was found. Two other mutants not yet characterized at the molecular level were also used for recombinational studies. From these data, a linear genetic map of the mitochondrial genome could be drawn. This map is consistent with the positions of the mutation sites on the mitochondrial DNA molecule and thereby validates the method used to generate the map. The frequency of recombination per physical distance unit (3.2% ± 0.7% per kilobase) is compared with those obtained for other organellar genomes in yeasts and Chlamydomonas.     

Further characterization of the respiratory deficient dum-1 mutation of Chlamydomonas reinhardtii and its use as a recipient for mitochondrial transformation

Summary The respiratory deficient dum-1 mutant of Chlamydomonas reinhardtii fails to grow in the dark because of a terminal 1.5 kb deletion in the linear 15.8 kb mitochondrial genome, which affects the apocytochrome b (CYB) gene. In contrast to the wild type where only mitochondrial genomes of monomer length are observed, the dum-1 genomes are present as a mixture of monomer and dimer length molecules. The mutant dimers appear to result from head-to-head fusions of two deleted molecules. Furthermore, mitochondrial genomes of dum-1 were also found to be unstable, with the extent of the deletion varying among single cell clones from the original mutant population. The dum-1 mutant also segregates, at a frequency of ca. 4% per generation, lethal minute colonies in which the original deletion now extends at least into the adjacent gene encoding subunit four of NAD dehydrogenase (ND4). We have used the dum-1 mutant as a recipient to demonstrate stable mitochondrial transformation in C. reinhardtii employing the biolistic method. After 4 to 8 weeks dark incubation, a total of 22 respiratory competent colonies were isolated from plates of dum-1 cells bombarded with C. reinhardtii mitochondrial DNA (frequency 7.3 × 10^–7) and a single colony was isolated from plates bombarded with C. smithii mitochondrial DNA (frequency 0.8 × 10^–7). No colonies were seen on control plates (frequency < 0.96 × 10^–9). All transformants grew normally in the dark on acetate media; 22 transformants were homoplasmic for the wild-type mitochondrial genome typical of the C. reinhardtii donor. The single transformant obtained from the C. smithii donor had a recombinant mitochondrial genome containing the donor CYB gene and the diagnostic HpaI and XbaI restriction sites in the gene encoding subunit I of cytochrome oxidase (COI) from the C. reinhardtii recipient. The characteristic deletion fragments of the dum-1 recipient were not detected in any of the transformants.     

Genetic mapping of mitochondrial markers by recombinational analysis in Chlamydomonas reinhardtii

The mitochondrial genome of Chlamydomonas reinhardtii is a 15.8 kb linear DNA molecule present in multiple copies. In crosses, the meiotic products only inherit the mitochondrial genome of the mating type minus (paternal) parent. In contrast mitotic zygotes transmit maternal and paternal mitochondrial DNA copies to their diploid progeny and recombinational events between molecules of both origins frequently occur. Six mitochondrial mutants unable to grow in the dark (dk^– mutants) were crossed in various combinations and the percentages of wild-type dk⁺ recombinants were determined in mitotic zygotes when all progeny cells had become homoplasmic for the mitochondrial genome. In crosses between strains mutated in the COB (apocytochrome ) gene and strains mutated in the COX1 (subunit 1 of cytochrome oxidase) gene, the frequency of recombination was 13.7% (± 3.2%). The corresponding physical distance between the mutation sites was 4.3 kb. In crosses between strains carrying mutations separated by about 20 bp, a recombinational frequency of 0.04% (± 0.02%) was found. Two other mutants not yet characterized at the molecular level were also used for recombinational studies. From these data, a linear genetic map of the mitochondrial genome could be drawn. This map is consistent with the positions of the mutation sites on the mitochondrial DNA molecule and thereby validates the method used to generate the map. The frequency of recombination per physical distance unit (3.2% ± 0.7% per kilobase) is compared with those obtained for other organellar genomes in yeasts and Chlamydomonas.     

Variable DNA splicing sites of a mitochondrial intron: relationship to the senescence process in Podospora

The unavoidable phenomenon of senescence in Podospora was previously shown to be correlated with the presence of a senescence-specific DNA originating from amplification of some regions of the mitochondrial chromosome. The most frequently amplified region (α) corresponds to the first intron of the gene coding for subunit one of cytochrome oxidase. Eleven long-lived mitochondrial mutants were isolated. Here we report sequencing experiments that show that three of them are deleted for most of intron α and for a few base pairs belonging to the upstream adjacent exon. We also report an analysis of the residual mitochondrial DNA associated with amplification of senescence-specific DNA α which allows us to identify, in senescent cultures, mitochondrial chromosomes lacking sequence α. These results taken together suggest that excision of intron α from the mitochondrial DNA occurs systematically during the aging process in Podospora. They furthermore provide the first example of inaccurate intron excision at the DNA level.     

Cytochrome oxidase subunit II gene in mitochondria of Oenothera has no intron

The cytochrome oxidase subunit II gene has been localized in the mitochondrial genome of Oenothera berteriana and the nucleotide sequence has been determined. The coding sequence contains 777 bp and, unlike the corresponding gene in Zea mays, is not interrupted by an intron. No TGA codon is found within the open reading frame. The codon CGG, as in the maize gene, is used in place of tryptophan codons of corresponding genes in other organisms. At position 742 in the Oenothera sequence the TGG of maize is changed into a CGG codon, where Trp is conserved as the amino acid in other organisms. Homologous sequences occur more than once in the mitochondrial genome as several mitochondrial DNA species hybridize with DNA probes of the cytochrome oxidase subunit II gene.     

DNA amplifications and deletions in Streptomyces lividans 66 and the loss of one end of the linear chromosome

Thirty-two 2-deoxygalactose-resistant mutants with DNA amplifications were isolated from Streptomyces lividans 66 strains carrying plasmid pMT664, which carries an agarase gene (dagA) and IS466. Thirty-one of the mutants carried amplified DNA sequences from a 70 kb region about 300 kb from one end of the linear chromosome in this species. In 28 of the mutants, all the wild-type sequences between the amplified region and the start of the 30 kb inverted repeat that forms the chromosome end were deleted. Thus, there appeared to be loss of one chromosome end and its replacement by the DNA amplification. In some mutants there amplification of a previously characterised 5.7 kb sequence that lies about 600 kb from the other chromosome end was also noted.     

Mitochondrial Genetics of Chlamydomonas Reinhardtii: Resistance Mutations Marking the Cytochrome B Gene

We describe the genetic and molecular analysis of the first non-Mendelian mutants of Chlamydomonas reinhardtii resistant to myxothiazol, an inhibitor of the respiratory cytochrome bc1 complex. Using a set of seven oligonucleotide probes, restriction fragments containing the mitochondrial cytochrome b (cyt b) gene from C. reinhardtii were isolated from a mitochondrial DNA library. This gene is located adjacent to the gene for subunit 4 of the mitochondrial NADH-dehydrogenase (ND4), near one end of the 15.8-kb linear mitochondrial genome of C. reinhardtii. The algal cytochrome b apoprotein contains 381 amino-acid residues and exhibits a sequence similarity of about 59% with other plant cytochrome b proteins. The cyt b gene from four myxothiazol resistant mutants of C. reinhardtii was amplified for DNA sequence analysis. In comparison to the wild-type strain, all mutants contain an identical point mutation in the cyt b gene, leading to a change of a phenylalanine codon to a leucine codon at amino acid position 129 of the cytochrome b protein. Segregation analysis in tetrads from reciprocal crosses of mutants with wild type shows a strict uniparental inheritance of this mutation from the mating type minus parent (UP-). However, mitochondrial markers from both parents are recovered in vegetative diploids in variable proportions from one experiment to the next for a given cross. On the average, a strong bias is seen for markers inherited from the mating type minus parent.     

Suppression of a +1 T mutation by a nearby substitution in the mitochondrial cox1 gene of Chlamydomonas reinhardtii : a new type of frameshift suppression in an organelle genome

In Chlamydomonas reinhardtii, mutants defective in the cytochrome pathway of respiration lack the capacity to grow under heterotrophic conditions (in darkness on acetate). In the dark^? strain dum18, a +1?T addition in a run of four Ts, located at codon 145 of the mitochondrial cox1 gene encoding subunit I of cytochrome c oxidase, is responsible for the mutant phenotype. A leaky revertant (su11) that grows heterotrophically at a lower rate than wild-type cells was isolated from dum18. Its respiration sensitivity to cyanide was low and its cytochrome c oxidase activity was only 4% of that of the wild-type enzyme. Meiotic progeny obtained from crosses between revertant and wild-type cells inherited the phenotype of the mt ^? parent, showing that the suppressor mutation, like dum18 itself, is located in the mitochondrial genome. In order to map the su11 mutation relative to dum18, a recombinational analysis was performed on the diploid progeny. It demonstrated that su11 was very closely linked to the dum18 mutation – less than 20–30?bp away. The cox1 gene of the su11 revertant was then sequenced. In addition to the +1?T frameshift mutation still present at codon 145, an A?→?C substitution was found at codon 146, leading to the replacement of a glutamic acid by an alanine in the polypeptide chain. No other mutations were detected in the cox1 coding sequence. As the new GCG codon (Ala) created at position 146 is very seldom used in the mitochondrial genome of C. reinhardtii, we suggest that the partial frameshift suppression by the nearby substitution is due to an occasional abnormal translocation of the ribosome (+1 base shift) facilitated both by the run of Ts and the low level of weak interaction of alanyl-tRNA.     

Shared molecular characteristics of successfully transformed mitochondrial genomes in <Emphasis Type="Italic">Chlamydomonas</Emphasis><Emphasis Type="Italic">reinhardtii</Emphasis>

Three types of respiratory deficient mitochondrial strains have been reported in Chlamydomonas reinhardtii: a deficiency due to (i) two base substitutions causing an amino acid change in the apocytochrome b (COB) gene (i.e., strain named dum-15), (ii) one base deletion in the COXI gene (dum-19), or (iii) a large deletion extending from the left terminus of the genome to somewhere in the COB gene (dum-1, -14, and -16). We found that these respiratory deficient strains of C. reinhardtii can be divided into two groups: strains that are constantly transformable and those could not be transformed in our experiments. All transformable mitochondrial strains were limited to the type that has a large deletion in the left arm of the genome. For these mitochondria, transformation was successful not only with purified intact mitochondrial genomes but also with DNA-constructs containing the compensating regions. In comparison, mitochondria of all the non-transformable strains have both of their genome termini intact, leading us to speculate that mitochondria lacking their left genome terminus have unstable genomes and might have a higher potential for recombination. Analysis of mitochondrial gene organization in the resulting respiratory active transformants was performed by DNA sequencing and restriction enzyme digestion. Such analysis showed that homologous recombination occurred at various regions between the mitochondrial genome and the artificial DNA-constructs. Further analysis by Southern hybridization showed that the wild-type genome rapidly replaces the respiratory deficient monomer and dimer mitochondrial genomes, while the E. coli vector region of the artificial DNA-construct likely does not remain in the mitochondria.     

Aging-related decrease in hepatic cytochrome oxidase of the Fischer 344 rat

The effect of aging on the hepatic mitochondrial population has been determined using a rigorously defined group of Fischer 344 rats with known survivorship data. The age groups studied included mature adult controls (8.5 months; 100% survivorship), an intermediate aged group (17.5 months; 90% survivorship), and an aged group (29 months; 20% survivorship). Cytochrome oxidase activity and content were determined in homogenates and mitochondrial fractions. The mitochondrial fractions were characterized by determination of respiratory activity, and monoamine oxidase activity as well as evaluation of the polypeptide composition by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and two-dimensional electrophoresis. The yield of protein in the isolated mitochondrial fraction as well as the mitochondrial specific content decreased significantly as a function of aging. Mitochondrial specific content was determined from the specific activities of cytochrome oxidase in the homogenate (per gram liver) and in the isolated mitochondrial fraction (per mg protein). Specific activity of hepatic cytochrome oxidase decreased approximately 15% (P = 0.035) in homogenates from the 17.5-month animals with a further, highly significant (P = 0.0002) decrease (29%) in the 29-month animals. In contrast, there was no statistically significant difference among the age groups in the cytochrome oxidase specific activity in the isolated hepatic mitochondrial fractions. However, the percentage of the total homogenate cytochrome oxidase activity recovered in the isolated mitochondrial fraction decreased significantly in the 29-month animals (P = 0.0063 vs the 8.5-month controls; P = 0.022 vs the 17.5-month group). Cytochrome aa₃ content of total liver homogenates from aged animals decreased (P = 0.00064) which is in agreement with the decline in cytochrome oxidase specific activity in this age group. In the mitochondrial fraction from the aged animals, cytochrome aa₃ content was essentially unchanged which is consistent with the lack of aging-related change in mitochondrial cytochrome oxidase specific activity. In freshly isolated mitochondrial fractions, no aging-related alterations were observed in respiratory control and $\text{ADP}\text{O}$ ratios. The addition of exogenous NADH and cytochrome c did not change significantly the respiratory rate of hepatic mitochondria from control or aged animals. These results demonstrate the integrity of freshly isolated mitochondrial preparations from both control and aged Fischer 344 rats. In addition, there was no aging-related alteration in either monoamine oxidase specific activity or polypeptide composition. The similarities observed in the specific activities of cytochrome oxidase and monoamine oxidase, as well as in the cytochrome aa₃ content and polypeptide composition of the isolated mitochondrial fraction, suggest a generalized decrease in hepatic mitochondrial content as a function of aging rather than a selective loss of mitochondrial components.     

Petite deletion map of the mitochondrial oxi3 region in Saccharomyces cerevisiae.

Summary 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.     

Localization in yeast mitochondrial DNA of mutations expressed in a deficiency of cytochrome oxidase and/or coenzyme QH2-cytochrome c reductase.

1. Three methods are described for the genetic analysis of yeast cytoplasmic mutants (mit- mutants) lacking cytochrome oxidase or coenzyme QH2-cytochrome c reductase. The procedures permit mutations in mitochondrial DNA to be mapped relative to each other and with respect to drug-resistant markers. The first method is based upon the finding that crosses of mit- mutants with some but not other isonuclear q- mutants lead to the restoration of respiratory functions. Thus a segment of mitochondrial DNA corresponding to a given mit- mutation or to a set of mutations can be delineated. The second method is based on the appearance of wild-type progeny in mit- X mit- crosses. The third one is based on the analysis of various recombinant classes issued from crosses between mit-, drug-sensitive and mit+, drug-resistant mutants. Representative genetic markers of the RIBI, OLII, OLI2 and PAR1 loci were used for this purpose. 2. The three methods when applied to the study of 48 mit- mutants gave coherent results. At least three distinct regions on mitochondrial DNA in which mutations cause loss of functional cytochrome oxidase have been established. A fourth region represented by closely clustered mutants lacking coenzyme QH2-cytochrome c reductase and spectrally detectable cytochrome b has also been studied. 3. The three genetic regions of cytochrome oxidase and the cytochrome b region were localized by the third method on the circular map, in spans of mitochondrial DNA defined by the drug-resistant markers. The results obtained by this method were confirmed by analysis of the crosses between selected mit- mutants and a large number of q- clones whose retained segments of mitochondrial DNA contained various combinations of drug-resistant markers. 4. All the genetic data indicate that the various regions studied are dispersed on the mitochondrial genome and in some instances regions or clusters of closely linked mutations involved in the same respiratory function (cytochrome oxidase) are separated by other regions which code for entirely different functions such as ribosomal RNA.     

The mitochondrial COB region in yeast codes for apocytochrome b and is mosaic.

Mitochondrial mutants of Saccharomyces cerevisiae defective in cytochrome b were analyzed genetically and biochemically in order to elucidate the role of the mitochondrial genetic system in the biosynthesis of this cytochrome. The mutants mapped between OLI1 and OLI2 on mitochondrial DNA in a region called COB. A fine structure map of the COB region was constructed by rho- deletion mapping and recombination analysis. The combined genetic and biochemical data indicate that the COB region is mosaic and contains at least five distinct clusters of mutants, A-E, with A being closest to OLI2 and E being closest to OLI1. Clusters A, C and E are probably coding regions for apocytochrome b, whereas clusters B and D seem to be involved in as yet unknown functions. These conclusions rest on the following evidence. 1. Most mutants in clusters A, C and E have specifically lost cytochrome b. Many of them accumulate smaller mitochondrial translation products; some of these were identified as fragments of apocytochrome b by proteolytic fingerprinting. The molecular weight of these fragments depends on the map position of the mutant, increasing in the direction OLI2 leads to OLI1. The mutant closest to OLI1 accumulates an apocytochrome b which is slightly larger than that of wild type. 2. A mutant in cluster C exhibits a spectral absorption band of cytochrome b that is shifted 1.5 nm to the red. 3. Mutants in clusters B and D are pleiotropic. A majority of them are conditional and lack the absorption bands of both cytochrome b and cytochrome aa3; these mutants also fail to accumulate apocytochrome b and subunit I of cytochrome c oxidase and instead form a large number of abnormal translation products whose nature is unknown. 4. Zygotic complementation tests reveal at least two complementation groups: The first group includes all mutants in cluster B and the second group includes mutants in clusters (A + C + D + E).     

Mitochondrial genes are found on minicircle DNA molecules in the mesozoan animal Dicyema

Animal mitochondrial DNA genomes are generally single circular molecules, 14-20 kb in size, containing a number of functional RNAs and 13 protein-coding genes. Among these, the COI, COII and COIII genes encode three subunits of cytochrome c oxidase. We have isolated and characterized these three mitochondrial genes from the mesozoan Dicyema, a primitive multicellular animal. Surprisingly, the COI, COII and COIII genes are encoded on three small, separate circular DNA molecules (minicircles) of length 1700, 1599 and 1697 bp, respectively. We estimated the copy number of each minicircle at 100 to 1000 per cell, and have shown a mitochondrial localization of the minicircles by in situ hybridization. Furthermore, we could not detect a putative "maxicircle" DNA molecule containing any combination of the COI, COII and COIII genes using either PCR or genomic Southern hybridization. Thus, our results show a novel mitochondrial genome organization in the mesozoan animal Dicyema.     

Mitochondrial and nuclear myxothiazol resistance in Saccharomyces cerevisiae

Summary Mitochondrial and nuclear mutants resistant to myxothiazol were isolated and characterized. The mitochondrial mutants could be assigned to two loci, myx1 and myx2, by allelism tests. The two loci map in the box region, the split gene coding for apocytochrome b. Locus myx1 maps in the first exon (box4/5) whereas myx2 maps in the last exon (box6). The nuclear mutants could be divided into three groups: two groups of recessive mutations and one of dominant mutations. Respiration of isolated mitochondria from mitochondrial mutants is resistant to myxothiazol. These studies support the conclusion that myxothiazol is an inhibitor of the respiratory chain of yeast mitochondria. The site of action of myxothiazol is mitochondrial cytochrome b.Abbreviations box mosaic gene coding for apocytochrome b - cyt b cytochrome b - MIC minimum inhibitory concentration - MNNG N-methyl-N'-nitro-N-nitrosoguanidine - Myx ^R/Myx ^S allelte forms of a locus conferring myxothiazol resistance - myx1, myx2 mitochondrial loci conferring myxothiazol resistance - rho ⁺/rho ^– grande/cytoplasmic petite - rho ⁰ cytoplasmic petite that is deleted of all mitochondrial DNA