pet 18: A chromosomal gene required for cell growth and for the maintenance of mitochondrial DNA and the killer plasmid of yeast

1978 ◽  
Vol 165 (2) ◽  
pp. 115-121 ◽  
Author(s):  
Michael J. Leibowitz ◽  
Reed B. Wickner
Keyword(s):  
Mitochondrial Dna ◽  
Cell Growth ◽  
Chromosomal Gene ◽  
Killer Plasmid

scholarly journals DELETION OF MITOCHONDRIAL DNA BYPASSING A CHROMOSOMAL GENE NEEDED FOR MAINTENANCE OF THE KILLER PLASMID OF YEAST

Genetics ◽  
1977 ◽  
Vol 87 (3) ◽  
pp. 441-452
Author(s):  
Reed B Wickner
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Mitochondrial Dna ◽  
Mitochondrial Genome ◽  
Antimycin A ◽  
Chromosomal Gene ◽  
Wild Type ◽  
Suppressor Mutations ◽  
Induced Mutants ◽  
Chromosomal Genes ◽  
Killer Plasmid

ABSTRACT Strains of Saccharomyces cerevisiae carrying a 1.4 × 106 dalton double-stranded (ds) RNA in virus-like particles (the killer plasmid or virus) secrete a toxin that is lethal to strains not carrying this plasmid (virus). The mak10 gene is one of 24 chromosomal genes (called pets, mak1, mak2,…) that are needed to maintain and replicate the killer plasmid. We report here isolation of spontaneous and induced mutants in which the killer plasmid is maintained and replicated in spite of a defect in the mak10 gene. The bypass (or suppressor) mutations in these strains are in the mitochondrial genome. Respiratory deficiency produced by various chromosomal pet mutations, by chloramphenicol, or by antimycin A, does not bypass the mak10-1 mutation. Several spontaneous mak10-1 killer strains have about 12-fold more of the killer plasmid ds RNA than do wild-type killers. Although the absence of mitochondrial DNA bypasses mak10-1, it does not bypass pets-1, mak1-1, mak3-1, mak4-1, mak5-1, mak6-1, mak7-1, or mak8-1.

scholarly journals Investigations of the mechanism by which mammalian cell growth is inhibited by N1N12-bis(ethyl)spermine

1993 ◽  
Vol 291 (1) ◽  
pp. 131-137 ◽  
Author(s):  
L Albanese ◽  
R J Bergeron ◽  
A E Pegg
Keyword(s):  
Mitochondrial Dna ◽  
Cell Growth ◽  
Cell Lines ◽  
Ornithine Decarboxylase ◽  
Polyamine Analogues ◽  
Proliferative Effect ◽  
L1210 Cells ◽  
Inhibition Of Growth ◽  
Variant Cell ◽  
Mammalian Cell Growth

N1N12-Bis(ethyl)spermine (BESM) and related compounds are powerful inhibitors of cell growth that may have potential as anti-neoplastic agents [Bergeron, Neims, McManis, Hawthorne, Vinson, Bortell and Ingeno (1988) J. Med. Chem. 31, 1183-1190]. The mechanism by which these compounds bring about their effects was investigated by using variant cell lines in which processes thought to be altered by these agents are perturbed. Comparisons between the response of these cells and of their parental equivalents to BESM, N1N11-bis(ethyl)norspermine, N1N14-bis(ethyl)homospermine and N1N8-bis(ethyl)spermidine were then made. It was found that D-R cells, an L1210-derived line that over-expresses ornithine decarboxylase, were not resistant to these compounds. This indicates that the decrease in ornithine decarboxylase is not critical for the action of the compounds on cell growth. Furthermore, although polyamine levels were decreased in the D-R cells, the content was not totally depleted, indicating that such depletion is also not essential for the anti-proliferative effect. Two cell lines lacking mitochondrial DNA (human 143B206 cells and chicken DU3 cells) did not differ in sensitivity to BESM from their parental 143BTK- and DU24 cells. Furthermore, the inhibition of respiration in L1210 cells in response to BESM developed more slowly than the inhibition of growth. Thus it appears that the inhibitions of mitochondrial DNA synthesis and of mitochondrial respiration are also not primary factors in the anti-proliferative effects of these polyamine analogues. The inhibition of growth did, however, correlate with the intracellular accumulation of the analogues. It appears that the bis(ethyl)polyamine derivatives act by binding to intracellular target molecules and preventing macromolecular synthesis. The decline in normal polyamines may facilitate such binding, but is not essential for growth arrest.

scholarly journals Somatic alterations in mitochondrial DNA produce changes in cell growth and metabolism supporting a tumorigenic phenotype

2012 ◽  
Vol 1822 (2) ◽  
pp. 293-300 ◽  
Author(s):  
Jana Jandova ◽  
Mingjian Shi ◽  
Kimberly G. Norman ◽  
George P. Stricklin ◽  
James E. Sligh
Keyword(s):  
Mitochondrial Dna ◽  
Cell Growth ◽  
Somatic Alterations

scholarly journals MUTANTS OF THE KILLER PLASMID OF SACCHAROMYCES CEREVISIAE DEPENDENT ON CHROMOSOMAL DIPLOIDY FOR EXPRESSION AND MAINTENANCE

Genetics ◽  
1976 ◽  
Vol 82 (2) ◽  
pp. 273-285
Author(s):  
Reed B Wickner
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Elevated Temperature ◽  
Mating Type ◽  
Chromosomal Gene ◽  
Wild Type ◽  
Opposite Mating Type ◽  
Diploid Clone ◽  
Wild Type Phenotype ◽  
Chromosomal Genes ◽  
Killer Plasmid

ABSTRACT Mutants of the killer plasmid of Saccharomyecs cerevisiaehave been isolated that depend upon chromosomal diploidy for the expression of plasmid functions and for replication or maintenance of the plasmid itself. These mutants are not defective in any chromosomal gene needed for expression or replication of the killer plasmid.—Haploids carrying these mutant plasmids (called d for diploid-dependent) are either unable to kill or unable to resist being killed or both and show frequent loss of the plasmid. The wild-type phenotype (K+R+) is restored by mating the d plasmid-carrying strain with either (a) a wild-type sensitive strain which apparently has no killer plasmid; (b) a strain which has been cured of the killer plasmid by growth at elevated temperature; (c) a strain which has been cured of the plasmid by growth in the presence of cycloheximide; (d) a strain which has lost the plasmid because it carries a mutation in a chromosomal mak gene; or (e) a strain of the opposite mating type which carries the same d plasmid and has the same defective phenotype, indicating that the restoration of the normal phenotype is not due to recombination between plasmid genomes or complementation of plasmid or chromosomal genes.—Sporulation of the phenotypically K+R+ diploids formed in matings between d and wild-type nonkiller strains yields tetrads, all four of whose haploid spores are defective for killing or resistance or maintenance of the plasmid or a combination of these. Every defective phenotype may be found among the segregants of a single diploid clone carrying a d plasmid. These defective segregants resume the normal killer phenotype in the diploids formed when a second round of mating is performed, and the segregants from a second round of meiosis and sporulation are again defective.

scholarly journals Effect of cobalt treatment on cell growth and mitochondrial DNA damage in HEK293 acutely exposed to hydrogen peroxide

2006 ◽  
Vol 20 (5) ◽  
Author(s):  
Yasutomo Nomura ◽  
Hiroyuki Fujiwara ◽  
Kohei Ito ◽  
Michihiko Sato ◽  
Eiji Takahashi ◽  
...  
Keyword(s):  
Hydrogen Peroxide ◽  
Dna Damage ◽  
Mitochondrial Dna ◽  
Cell Growth ◽  
Mitochondrial Dna Damage

scholarly journals A Mitochondrial DNA Primase Is Essential for Cell Growth and Kinetoplast DNA Replication in Trypanosoma brucei

2010 ◽  
Vol 30 (6) ◽  
pp. 1319-1328 ◽  
Author(s):  
Jane C. Hines ◽  
Dan S. Ray
Keyword(s):  
Mitochondrial Dna ◽  
Dna Replication ◽  
Cell Growth ◽  
Trypanosoma Brucei ◽  
Dna Polymerase ◽  
Rnase H ◽  
Kinetoplast Dna ◽  
African Trypanosomes ◽  
Dna Primase

ABSTRACT Kinetoplast DNA in African trypanosomes contains a novel form of mitochondrial DNA consisting of thousands of minicircles and dozens of maxicircles topologically interlocked to form a two-dimensional sheet. The replication of this unusual form of mitochondrial DNA has been studied for more than 30 years, and although a large number of kinetoplast replication genes and proteins have been identified, in vitro replication of these DNAs has not been possible since a kinetoplast DNA primase has not been available. We describe here a Trypanosoma brucei DNA primase gene, PRI1, that encodes a 70-kDa protein that localizes to the kinetoplast and is essential for both cell growth and kinetoplast DNA replication. The expression of PRI1 mRNA is cyclic and reaches maximum levels at a time corresponding to duplication of the kinetoplast DNA. A 3′-hydroxyl-terminated oligoriboadenylate is synthesized on a poly(dT) template by a recombinant form of the PRI1 protein and is subsequently elongated by DNA polymerase and added dATP. Poly(dA) synthesis is dependent on both PRI1 protein and ATP and is inhibited by RNase H treatment of the product of PRI1 synthesis.

scholarly journals A High-Order Trans-Membrane Structural Linkage Is Responsible for Mitochondrial Genome Positioning and Segregation by Flagellar Basal Bodies in Trypanosomes

2003 ◽  
Vol 14 (5) ◽  
pp. 1769-1779 ◽  
Author(s):  
Emmanuel O. Ogbadoyi ◽  
Derrick R. Robinson ◽  
Keith Gull
Keyword(s):  
Cell Cycle ◽  
Mitochondrial Dna ◽  
Cell Growth ◽  
Mitochondrial Genome ◽  
S Phase ◽  
High Order ◽  
Basal Bodies ◽  
Kinetoplast Dna ◽  
Mitochondrial Membranes ◽  
Extreme Form

In trypanosomes, the large mitochondrial genome within the kinetoplast is physically connected to the flagellar basal bodies and is segregated by them during cell growth. The structural linkage enabling these phenomena is unknown. We have developed novel extraction/fixation protocols to characterize the links involved in kinetoplast-flagellum attachment and segregation. We show that three specific components comprise a structure that we have termed the tripartite attachment complex (TAC). The TAC involves a set of filaments linking the basal bodies to a zone of differentiated outer and inner mitochondrial membranes and a further set of intramitochondrial filaments linking the inner face of the differentiated membrane zone to the kinetoplast. The TAC and flagellum-kinetoplast DNA connections are sustained throughout the cell cycle and are replicated and remodeled during the periodic kinetoplast DNA S phase. This understanding of the high-order trans-membrane linkage provides an explanation for the spatial position of the trypanosome mitochondrial genome and its mechanism of segregation. Moreover, the architecture of the TAC suggests that it may also function in providing a structural and vectorial role during replication of this catenated mass of mitochondrial DNA. We suggest that this complex may represent an extreme form of a more generally occurring mitochondrion/cytoskeleton interaction.

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