Relationship between Dimorphology and Respiration in Mucor genevensis Studied with Chloramphenicol

Growth of Mucor genevensis, a facultatively anaerobic dimorphic mold, in high concentrations of chloramphenicol (4 mg/ml) leads to increased numbers of yeast-like cells and small club-like mycelial forms. This change in morphology is accompanied by a threefold increase in the mass doubling time, the loss of cyanide-sensitive respiration, and the development of cyanide-insensitive respiration. Associated with these changes is the absence of cytochromes aa(3) and b and the inability of the organism to utilize ethanol; in addition, mitochondria appear more numerous and have less internal membrane. A further inhibitory action of the antibiotic, other than eliminating functional mitochondria, appears likely since microaerobic cultures which lack respiratory ability have twice the mass doubling time in the presence of the drug. Although a small inhibition of amino acid incorporation by cytoplasmic ribosomes is found with a high chloramphenicol concentration, it is insufficient to account for the effect on growth of the microaerobic culture. The nature of this additional effect of chloramphenicol remains to be determined, but it has been shown that increasing the glucose concentration can partially reverse this action of the antibiotic. The effect of the drug on the morphology of the organism is not as dramatic as that of phenethyl alcohol in producing yeast-like forms. However, in view of the action of chloramphenicol in eliminating functional mitochondria in M. genevensis the suggestion that phenethyl alcohol exerts its effect in promoting yeast-like morphology by uncoupling oxidative phosphorylation should be re-examined.     

Elevated Levels of Petite Formation in Strains of SACCHAROMYCES CEREVISIAE Restored to Respiratory Competence. I. Association of Both High and Moderate Frequencies of Petite Mutant Formation with the Presence of Aberrant Mitochondrial DNA

When recently arisen spontaneous petite mutants of Saccharomyces cerevisiae are crossed, respiratory competent diploids can be recovered. Such restored strains can be divided into two groups having sectored or unsectored colony morphology, the former being due to an elevated level of spontaneous petite mutation. On the basis of petite frequency, the sectored strains can be subdivided into those with a moderate frequency (5–16%) and those with a high frequency (>60%) of petite formation. Each of the three categories of restored strains can be found on crossing two petites, suggesting either that the parental mutants contain a heterogeneous population of deleted mtDNAs at the time of mating or that different interactions can occur between the defective molecules. Restriction endonuclease analysis of mtDNA from restored strains that have a wild-type petite frequency showed that they had recovered a wild-type mtDNA fragmentation pattern. Conversely, all examined cultures from both categories of sectored strains contained aberrant mitochondrial genomes that were perpetuated without change over at least 200 generations. In addition, sectored colony siblings can have different aberrant mtDNAs. The finding that two sectored, restored strains from different crosses have identical but aberrant mtDNAs provides evidence for preferred deletion sites from the mitochondrial genome. Although it appears that mtDNAs from sectored strains invariably contain duplications, there is no apparent correlation between the size of the duplication and spontaneous petite frequency.     

A vital function for mitochondrial DNA in the petite-negative yeastKluyveromyces lactis

Petite-negative yeasts do not form viable respiratory-deficient mutants on treatment with DNA-targeting drugs that readily eliminate the mitochondial DNA (mtDNA) from petite-positive yeasts. However, in the petite-negative yeastKluyveromyces lactis, specific mutations in the nuclear genesMGI2 andMGI5 encoding the- and-subunits of the mitochondrial F₁-ATPase, allow mtDNA to be lost. In this study we show that wild-typeK. lactis does not survive in the absence of its mitochondrial genome and that the function ofmgi mutations is to suppress lethality caused by loss of mtDNA. Firstly, we find that loss of a multicopy plasmid bearing amgi allele readily occurs from a wild-type strain with functional mtDNA but is not tolerated in the absence of mtDNA. Secondly, we cloned theK. lactis homologue of theSaccharomyces cerevisiae mitochondrial genome maintenance geneMGM101, and disrupted one of the two copies in a diploid. Following sporulation, we find that segregants containing the disrupted gene form minicolonies containing 6-8000 inviable cells. By contrast, disruption ofMGM101 is not lethal in a haploidmgi strain with a specific mutation in a subunit of the mitochondrial F₁-ATPase. These observations suggest that mtDNA inK. lactis encodes a vital function which may reside in one of the three mitochondrially encoded subunits of F₀.     

Conversion at large intergenic regions of mitochondrial DNA in Saccharomyces cerevisiae.

Saccharomyces cerevisiae mitochondrial DNA deletion mutants have been used to examine whether base-biased intergenic regions of the genome influence mitochondrial biogenesis. One strain (delta 5.0) lacks a 5-kilobase (kb) segment extending from the proline tRNA gene to the small rRNA gene that includes ori1, while a second strain (delta 3.7) is missing a 3.7-kb region between the genes for ATPase subunit 6 and glutamic acid tRNA that encompasses ori7 plus ori2. Growth of these strains on both fermentable and nonfermentable substrates does not differ from growth of the wild-type strain, indicating that the deletable regions of the genome do not play a direct role in the expression of mitochondrial genes. Examination of whether the 5- or 3.7-kb regions influence mitochondrial DNA transmission was undertaken by crossing strains and examining mitochondrial genotypes in zygotic colonies. In a cross between strain delta 5.0, harboring three active ori elements (ori2, ori3, and ori5), and strain delta 3.7, containing only two active ori elements (ori3 and ori5), there is a preferential recovery of the genome containing two active ori elements (37% of progeny) over that containing three active elements (20%). This unexpected result, suggesting that active ori elements do not influence transmission of respiratory-competent genomes, is interpreted to reflect a preferential conversion of the delta 5.0 genome to the wild type (41% of progeny). Supporting evidence for conversion over biased transmission is shown by preferential recovery of a nonparental genome in the progeny of a heterozygous cross in which both parental molecules can be identified by size polymorphisms.     

Nitrate Reductase and Soluble Cytochrome c in Spirillum itersonii

The addition of nitrate to cultures of Spirillum itersonii incubated under low aeration produced a diauxic growth pattern in which the second exponential phase was preceded by the appearance of nitrite in the medium. The organism also grew anaerobically in the presence of nitrate. Nitrate reductase activity could be demonstrated in cell-free extracts by use of reduced methyl viologen as the electron donor. The enzyme was located in the supernatant fraction after centrifugation of extracts for 2 hr at 40,000 x g, and it sedimented as a single peak when centrifuged in a sucrose gradient. Nitrate reductase activity was found in cells grown with low aeration without nitrate, but was increased about twofold by addition of nitrate. Enzyme activity was negligible in cells grown with high aeration. The proportion of soluble cytochrome c was increased two- to threefold in cells grown with nitrate. The specific activities of nitrate reductase and soluble cytochrome c rose when nitrate or nitrite was added to cell suspensions incubated with low aeration; nitrite was more effective than nitrate during the early stages of incubation. A nitrate reductase-negative mutant synthesized increased amounts of soluble cytochrome c in response to nitrate or to nitrite in the cell suspension system. It is concluded that enhanced synthesis of soluble cytochrome c does not require the presence of a functional nitrate reductase.     

Association of Microcyst Formation in Spirillum itersonii with the Spontaneous Induction of a Defective Bacteriophage

Mitomycin C and ultraviolet light were found to induce the formation of microcysts in Spirillum itersonii. These forms, as well as spontaneously occurring microcysts in this species, were found to contain phage tail parts, rhapidosomes, and a granular substance not seen in normal cells. It is suggested that microcysts are formed as the result of the induction of a defective phage. The production of phage lysozyme within the cell could lead to the formation of spherical forms as the cells lose their structural mucopeptide layer. Complete virus particles were not seen, nor was any biological activity demonstrated when the induced cultures were tested against two other strains of S. itersonii. The other strains of this bacterium also formed microcysts and phage tail parts when induced with mitomycin. Attempts to isolate an organism lacking the defective phage have been unsuccessful.     

THE BIOGENESIS OF MITOCHONDRIA IN SACCHAROMYCES CEREVISIAE : A Comparison between Cytoplasmic Respiratory-Deficient Mutant Yeast and Chloramphenicol-Inhibited Wild Type Cells

The effects of chloramphenicol on S. cerevisiae and on a cytoplasmic respiratory-deficient mutant derived from the same strain are compared. In the normal yeast, high concentrations of chloramphenicol in the growth medium completely inhibit the formation of cytochromes a, a₃, b, and c₁ and partially inhibit succinate dehydrogenase formation, whereas they do not affect cytochrome c synthesis. This has been correlated with the marked reduction of mitochondrial cristae formation in the presence of the drug. In glucose-repressed normal yeast, chloramphenicol has little effect on the formation of outer mitochondrial membrane, or on the synthesis of malate dehydrogenase and fumarase. However, both these enzymes, as well as the number of mitochondrial profiles, are markedly decreased when glucose de-repressed yeast is grown in the presence of chloramphenicol. The antibiotic did not appear to affect the cytoplasmic respiratory-deficient mutant. The results have been interpreted to indicate that chloramphenicol inhibits the protein-synthesizing system characteristic of the mitochondria. Since the drug does not prevent the formation of cytochrome c, of several readily solubilized mitochondrial enzymes, or of outer mitochondrial membrane, it is suggested that these are synthesized by nonmitochondrial systems.