Mitochondrial DNA synthesis during fungal spore germination

Summary Germinating spores of the fungus Botryodiplodia theobromae incorporated guanine-8-C¹⁴ into both the nuclear DNA and mitochondrial DNA fractions. Ethidium bromide inhibited the synthesis of mitochondrial DNA without having a significant effect on nuclear DNA synthesis or on the rate and extent of spore germination. Rates of leucine and uracil incorporation and of oxygen uptake were not significantly affected by ethidium bromide until germination was nearly completed. Mitochondrial DNA synthesis is apparently not required for germination of the spores of B. theobromae but is probably essential to continued vegetative growth.Abbreviations DNA deoxyribonucleic acid - mit-DNA mitochondrial DNA - nuc-DNA nuclear DNA - RNA ribonucleic acid - EB ethidium bromide - Tris tris (hydroxymethyl)aminomethane Published with the approval of the Director as Paper No. 3331, Journal Series, Nebraska Agricultural Experiment Station. Research reported was conducted under Project No. 21-17. Paper No. 7877, Scientific Journal Series, Minnesota Agricultural Experiment Station.     

Effects of Ethidium Bromide and Several Acridine Dyes on the Kinetoplast DNA of Leishmania tropica*†

Whole cell DNA from Leishmania tropica has 2 peaks when banded by CsCl equilibrium density centrifugation. The main band has a buoyant density of 1.721 and the satellite band a buoyant density of 1.705, with Clostridium perfringens DNA (ρ= 1.6915) used as a reference. The satellite band has been identified as the kinetoplast DNA by purifying DNA from isolated kinetoplasts. L. tropica has the highest G + C content of both nuclear and kinetoplastic DNA thus far reported for trypanosomatids. The effects of ethidium bromide, acriflavin, proflavin, and 5-aminoacridine on the kinetoplast of L. tropica have been compared. Ethidium bromide and acriflavin, but not proflavin or 5-aminoacridine, induce dyskinetoplasty. L. tropica is one of the most sensitive trypanosomatids to ethidium bromide and acriflavin. Examination of the DNA from drug-treated cells in CsCl gradients revealed a loss of the satellite band after ethidium bromide or acriflavin treatment, but not after proflavin or 5-aminoacridine treatment. Cell division was required to produce these effects on the kinetoplast.     

Mechanism of the Heat Sensitization of Bacillus subtilis Spores by Ethidium Bromide

Pretreatment with ethidium bromide (5 μg/ml) followed by a water wash had no effect on unheated Bacillus subtilis spores, but the viability of these spores after heating was much lower than that of similarly heated spores exposed to water alone. The fate of water- or ethidium bromide-treated spores, unheated or heated, was followed by allowing them to germinate and outgrow in a minimal or a complex liquid medium. Spores exposed to ethidium bromide and then heated (85°C, 10 min) exhibited a developmental block during germination and outgrowth. Many of them were blocked at the stage when the bacterium emerged from the germinated spore. When 0.35 μg of ethidium bromide per ml was added to heated spores in the germination-growth medium, the outgrowth of heated spores was inhibited to the same extent as were pretreated spores. Ethidium bromide acted in the first hour of germination of heated spores since addition after this time was ineffective in inhibiting recovery events. Repair of heat-damaged spore DNA was detected during the first 2 h of germination. The addition of ethidium bromide (final concentration, 0.35 μg/ml) inhibited DNA repair during early outgrowth. Increased sensitivity of spores to heat after pretreatment with sublethal concentrations of ethidium bromide was due to the inhibition of the repair of heat-damaged DNA.     

Effect of drugs on deoxyribonucleic acid synthesis in isolated mammalian cell nuclei. Comparison with partially purified deoxyribonucleic acid polymerases.

In order to ascertain the identity of the DNA-dependent DNA polymerase responsible for the observed DNA synthesis in nuclei isolated from baby-hamster kidney (BHK-21/C13) cells a comparative study was carried out on the effects of some drugs, reported to influence DNA synthesis, on DNA synthesis catalysed by these nuclei and by partially purified DNA polymerase-alpha and -beta. In all cases DNA synthesis by isolated nuclei and polymerase-alpha was inhibited to similar extents by N-ethylmaleimide, p-hydroxymercuribenzoate, novobiocin, heparin and phosphonoacetic acid; polymerase-beta was much less affected by these compounds. Ethidium bromide inhibited all DNA synthesis to similar extents, although at low concentrations (about 2 microgram/ml) synthesis in isolated nuclei was stimulated. The results are discussed in relation to the proposal that DNA polymerase-alpha catalyses the covalent extension of Okazaki fragments that these nuclei carry out in vitro.     

Methylglyoxal bis(guanylhydrazone) elimination of polyamine effects on protein synthesis

The effect of methylglyoxal bis(guanylhydrazone) (MGBG), a structural analog of polyamines, on protein synthesis has been studied in the presence and absence of spermidine. The spermidine stimulation of polyphenylalanine- and MS2 RNA-directed RNA replicase synthesis in an Escherichia coli cell-free system and of globin synthesis in a rabbit reticulocyte cell-free system disappeared with the addition of MGBG. The spermidine reduction of misincorporation of leucine during polyphenylalanine synthesis in both E. coli and wheat germ cell-free systems was also disturbed by MGBG. MGBG noncompetitively interfered with polyamine stimulation of polyphenylalanine and globin synthesis, suggesting that MGBG could bind to both RNA and the complex of RNA and polyamine. MGBG was preferentially bound to ribosomal RNA among ribosomal RNA, poly(U), and calf thymus DNA, and strongly inhibited the amount of polyamine bound to ribosomal RNA. These results suggest that MGBG elimination of polyamine effects on protein synthesis may occur through the disturbance of polyamine binding to ribosomal RNA.     

Lack of influence of mitochondrial genetical information on the multiplication of Herpes simplex virus in HeLa cells

Mitochondrial DNA synthesis in HeLa cells is inhibited by 0.2 μg ethidium bromide/ml whereas nuclear DNA synthesis is essentially unimpaired under the same conditions. The action of ehtidium bromide on mitochondrial DNA appears to be completed within 18 hours of exposure to the drug. Total cellular macromolecular synthesis under ethidium bromide is initially decreased and at later times slightly stimulated. Ethidium bromide pretreatment of HeLa cells did not significantly affect the multiplication of Herpes simplex virus as compared with that in control cells.     

An ethidium bromide-agarose plate assay for the nonradioactive detection of cDNA synthesis

Ethidium bromide was used to determine the success of cDNA synthesis reactions. Since ethidium bromide in agarose can be used to quantitate RNA and DNA, conditions under which the greater fluorescence of double-stranded DNA (dsDNA) is utilized were devised to assay dsDNA synthesis from mRNA. Ethidium bromide at 5 micrograms/ml in agarose allowed quantitative detection of cDNA in the range of 0.03 to 0.0015 microgram. Sodium dodecyl sulfate had an adverse effect on the measurement of cDNA. Subsequent cDNA analysis by alkaline gel electrophoresis and staining in 5 micrograms/ml ethidium bromide allowed accurate and rapid sizing of cDNA and required only 0.1-0.05 microgram cDNA.     

Regulation of RNA polymerase subunit synthesis in Escherichia coli: utilization of DNA-Intercalating drugs as a probe.

The effect of four DNA-intercalating drugs on the synthesis of the β and β′ subunits of Escherichia coli RNA polymerase was investigated. Acridine orange, proflavine, ethidium bromide, and berberine sulfate at sublethal doses caused a general reduction in cellular RNA and protein syntheses. Under this condition, acridine orange and proflavine rapidly led to overproduction of the β and β′ subunits in significant amounts. Ethidium bromide and berberine sulfate also caused overproduction of the two subunits but with a delay of 10 min at 30 °C. The β and β′ subunits of RNA polymerase became the major proteins being synthesized by E. coli cells after prolonged treatment with DNA-intercalating drugs. The level of the α subunit of RNA polymerase was not altered by any of the drugs tested. The overproduction of the β and β′ subunits induced by DNA-intercalating drugs is shown to require de novo synthesis of the ββ′ mRNA. These findings indicate that the expression of the ββ′ operon is regulated and that the synthesis of the α subunit is not regulated by the mechanism regulating the ββ′ operon. Taken together with evidence reported by others, these results strongly suggest that the concentration of intracellular free RNA polymerase plays a role in regulating the expression of the ββ′ operon.     

Mode of Action of Lomofungin

Lomofungin inhibited the growth of some yeasts and mycelial fungi at concentrations between 5 and 10 μg/ml. At such concentrations, there was no decrease in endogenous and exogenous oxygen consumption, and even 50 μg of antibiotic per ml caused only slight decreases. The permeation of the cell membrane was changed so that leakage of ninhydrin-positive substances was reduced, and the uptake of ¹⁴C-labeled glucose, amino acids, uracil, and thymidine was decreased at concentrations as low as 4 μg/ml. Protein synthesis in whole cells of Saccharomyces cerevisiae was reduced 35% at 10 μg/ml. However, the antibiotic did not reduce the incorporation of phenylalanine-U-¹⁴C into polypeptides with cell-free systems of Rhizoctonia solani and S. cerevisiae. The synthesis of ribonucleic acid (RNA) and deoxyribonucleic acid (DNA) was inhibited even at concentrations of lomofungin of 4 μg/ml. Since RNA synthesis was inhibited at lower concentrations and earlier than DNA synthesis, the primary site of action of the antibiotic appears to be the synthesis of RNA.     

Mode of Action of Lomofungin

Lomofungin inhibited the growth of some yeasts and mycelial fungi at concentrations between 5 and 10 μg/ml. At such concentrations, there was no decrease in endogenous and exogenous oxygen consumption, and even 50 μg of antibiotic per ml caused only slight decreases. The permeation of the cell membrane was changed so that leakage of ninhydrin-positive substances was reduced, and the uptake of ¹⁴C-labeled glucose, amino acids, uracil, and thymidine was decreased at concentrations as low as 4 μg/ml. Protein synthesis in whole cells of Saccharomyces cerevisiae was reduced 35% at 10 μg/ml. However, the antibiotic did not reduce the incorporation of phenylalanine-U-¹⁴C into polypeptides with cell-free systems of Rhizoctonia solani and S. cerevisiae. The synthesis of ribonucleic acid (RNA) and deoxyribonucleic acid (DNA) was inhibited even at concentrations of lomofungin of 4 μg/ml. Since RNA synthesis was inhibited at lower concentrations and earlier than DNA synthesis, the primary site of action of the antibiotic appears to be the synthesis of RNA.     

Direct action of ethidium bromide upon mitochondrial oxidative phosphorylation and morphology.

Ethidium bromide (23 nmol/mg of protein) was found to be a potent inhibitor of oxidative phosphorylation, as determined by loss of respiratory control through the inhibition of the ADP-induced state-3 rate of oxygen uptake. A time latency for complete loss of respiratory control was noted, after which 2,4-dinitrophenol (DNP) was ineffective in overcoming this inhibition. In the absence of EDTA, ethidium bromide produced an apparent uncoupling, as evidenced by an increase of state-4 rates of oxygen uptake and loss of respiratory control. As low as 8 nmol of ethidium bromide/mg of protein stimulated mitochondrial adenosine triphosphatase (ATPase) for 5 min. Two to three times this amount of ethidium bromide reduced the amount P_i released. Preincubation of mitochondria with ethidium bromide prevented subsequent release of P_i during incubation with ATP. Likewise, preincubation inhibited the DNP-activated ATPase. The uptake of low levels of [¹⁴C]ADP preincubated with ethidium bromide (14 nmol/mg of protein) and succinate or α-ketoglutarate could apparently be reversed, with loss of radioactivity beginning several minutes after addition of the radioactive nucleotide. Inhibition of oxidative phosphorylation by ethidium bromide may be due to modification of the adenine nucleotide transport system in mitochondria. The production of apparently swollen mitochondria treated in vitro with ethidium bromide and substrates necessary for oxidative phosphorylation, as seen in electron micrographs, further indicates that the compound is capable of acting directly upon mouse liver mitochondrial function and structure.     

Effect of methylglyoxal bis (guanylhydrazone) (MGBG) in vivo on the decarboxylation of s-adenosylmethionine and synthesis of spermidine in the rat and guinea pig.

The rates of decarboxylation of $\text{S}$-adenosylmethionine and synthesis of spermidine have been measured in extracts of liver, kidney and brain of the rat and guinea pig after intraperitoneal injection of MGBG, both before and after dialysis. The rate of decarboxylation of $\text{S}$-adenosylmethionine paralleled that of spermidine synthesis in all of the tissues investigated, even when spermidine synthesis was measured using preformed decarboxylated $\text{S}$-adenosylmethionine as substrate instead of $\text{S}$-adenosylmethionine itself. MGBG inhibited CO₂ production and spermidine synthesis to a similar extent in extracts of liver and kidney of both the rat and the guinea pig. After dialysis, a similar increase in both CO₂ production and spermidine synthesis was noted in these extracts. No effects on CO₂ production or spermidine synthesis were noted on extracts of brain of the rat or guinea pig, either before or after dialysis. When MGBG was injected intracisternally, CO₂ production and spermidine synthesis by extracts of brain were inhibited to the same extent, and after dialysis a similar increase in CO₂ production and spermidine synthesis was observed. These results indicate that the effects of MGBG are essentially the same in brain as they are in liver and kidney, and the MGBG injected intraperitoneally does not pass into the brain.     

Effects of protein inhibitors and auxin on nucleic Acid metabolism in peanut cotyledons

The accumulation of labeled phosphorus into newly synthesized nucleic acids or peanut cotyledon slices incubated with chloramphenicol, puromycin, or 2,4-dichlorophenoxyacetic acid (2,4-D) was reduced. Promotion of nucleic acid synthesis was not noted by any of these chemicals. Chloramphenicol completely inhibited the synthesis of the DNA-RNA fraction at 1.25 × 10⁻³ m while soluble and ribosomal RNA was inhibited by 70% and 80%, respectively. At the same concentration messenger RNA was inhibited by only 40%. These effects suggest that chloramphenicol inhibit nucleic acid synthesis in peanut cotyledons in a differential manner. Similar results were noted for DNA at low concentrations of 2,4-D. However, at high concentrations of 2,4-D, DNA as well as RNA fractions were inhibited in a similar manner at a given concentration. Puromycin did not differentially inhibit nucleic acid synthesis except at 2 × 10⁻³ m where DNA was least inhibited.     

The metabolic effects and uptake of ethidium bromide by rat liver mitochondria.

The uptake of ethidium bromide by rat liver mitochondria and its effect on mitochondria, submitochondrial particles, and F₁ were studied. Ethidium bromide inhibited the State 4-State 3 transition with glutamate or succinate as substrates. With glutamate, ethidium bromide did not affect State 4 respiration, but with succinate it induced maximal release of respiration. These effects appear to depend on the uptake and concentration of the dye within the mitochondrion. In submitochondrial particles, the aerobic oxidation of NADH is much more sensitive to ethidium bromide than that of succinate. Ethidium bromide partially inhibited the ATPase activity of submitochondrial particles and of a soluble F₁ preparation. Ethidium bromide behaves as a lipophilic cation which is concentrated through an energy-dependent process within the mitochondria, producing its effects at different levels of mitochondrial function. The ability of mitochondria to concentrate ethidium bromide may be involved in the selectivity of the dye as a mitochondrial mutagen.     

The effect of formycin B on mRNA translation and uptake of purine precursors in Leishmania mexicana

Formycin B is a structural analog of inosine that is a potent inhibitor of Leishmania multiplication. Formycin B is reportedly converted to formycin A nucleotides and incorporated into RNA by the organisms, and it is unclear whether the active form of the drug is the nucleoside itself or its several metabolites. We confirmed that formycin A nucleotides are formed by formycin B-exposed L. mexicana promastigotes, and determined that the intraparasite concentration of Formycin B and its metabolites was 6 times the extracellular formycin B concentration. Formycin B did not significantly inhibit purine nucleoside transport by intact promastigotes or purine base phosphoribosylation by parasite lysates. Thus, the nucleoside does not appear to inhibit these initial steps of purine nucleoside metabolism. Since RNA and protein synthesis in formycin B-treated intact promastigotes was found to be inhibited within 30 minutes, the effect of formycin A metabolites on leishmanial protein synthesis was investigated in in vitro protein synthesis experiments. Messenger RNA from formycin B-treated promastigotes was translated only 40% as efficiently as control promastigote mRNA by rabbit reticulocyte lysates. In addition, when formycin A-5'-triphosphate was preincubated with the rabbit reticulocyte lysates, translation of control mRNA was 86% inhibited. Formycin B toxicity to Leishmania promastigotes appears to be at least partially due to inhibition of protein synthesis by formycin A nucleotides and formycin A containing mRNA.     

Molecular specificity of 2-aminopurine in Saccharomyces cerevisiae

The rates of DNA, RNA and protein synthesis were investigated by incorporation of radioactive precursors into the excised root tips of V. faba. 2-h exposure to 0.1% caffeine resulted in inhibition of protein synthesis to about 60% of the control rate. RNA synthesis was reduced in the range of 20–30%. The same concentration of caffeine did not affect the rate of DNA synthesis even during 12-h incubation, but concentrations higher than 1% caused a significant decrease in [³H]thymidine incorporation.     

Isolation of viral RNA using cesium chloride-ethidium bromide equilibrium sedimentation

The effect of ethidium bromide (EB) on the buoyant density of reovirus RNA during equilibrium sedimentation has been investigated. The addition of the dye ethidium bromide was found to reduce the buoyant density of reovirus RNA in a Cs₂SO₄ gradient by a value of 0.13 to 0.15 g/cc, and provided a separation limit of 0.10 g/cc relative to the ? of marker DNA. Ethidium bromide was found also to reduce the ? of reovirus RNA to allow this RNA to band on a CsCl gradient. The separation factor between DNA and RNA on a CsCl-EB gradient was found to be 0.23 g/cc, indicating this type of gradient to be highly effective for separating the two types of polynucleotides.