Intracellular binding of ethidium studied by photoaffinity labeling in vivo.

The azide analog of 14C-labeled ethidium bromide was mixed with yeast cells and when photolyzed by visible light, formed covalent complexes with all yeast cell organelles. The 14C counts were found in DNA, RNA and protein of yeast subcellular fractions, illustrating the complexity of binding of a drug which appears highly specific in its actions.     

Intracellular binding of ethidium studied by photoaffinity labeling in vivo

The azide analog of ¹⁴C-labeled ethidium bromide was mixed with yeast cells and when photolyzed by visible light, formed covalent complexes with all yeast cell organelles. The ¹⁴C counts were found in DNA, RNA and protein of yeast subcellular fractions, illustrating the complexity of binding of a drug which appears highly specific in its actions.     

Sidedness of inhibition of energy transduction in oxidative phosphorylation in rat liver mitochondria by ethidium bromide.

Ethidium bromide, a new type of inhibitor of energy transduction in oxidative phosphorylation, inhibited ATP synthesis in intact mitochondria but not in submitochondrial particles, the latter being inside-out relative to the membranes of intact mitochondria. Ethidium bromide incorporated inside the submitochondrial particles inhibited ATP synthesis in the particles. The decrease of the membrane potential by valinomycin (plus KCl) inhibited only slightly the energy-dependent binding of ethidium bromide to the mitochondria. The present results show clearly that ethidium bromide inhibited energy transduction in oxidative phosphorylation by acting on the outer side (C-side) of the inner mitochondrial membrane, perhaps by neutralizing negative charges created on the surface of the C-side, and that it had no inhibitory activity on the inner side (M-side) of the membrane. Th present results show also that the energy-dependent binding of ethidium is not due to electrophoretic transport down the membrane potential; ethidium may bind to negative charges on the surface of the C-side. The present study suggest that an anisotropic distribution of electric charge in the inner mitochondrial membrane is an intermediary high energy state of oxidatvie phosphorylation.     

Retention of cytoplasmic killer determinants in yeast cells after removal of mitochondrial DNA by ethidium bromide

Summary The killer character in yeast shows cytoplasmic inheritance. Killer cells were treated with ethidium bromide and their DNA subsequently examined by caesium chloride density gradient centrifugation. Under conditions in which more than 94% of detectable mitochondrial DNA is lost, more than 99% of the cells retain the killer phenotype. It is concluded that the killer genetic determinants are unlikely to be part of the mitochondrial genome.     

Lectin histochemical studies of mouse granulated metrial gland cells

A lectin histochemical study has been carried out on mouse granulated metrial gland cells, the major leucocyte population that differentiates in the uterine wall in pregnancy. The binding characteristics of 26 lectins were examined using light microscopical methods. Fourteen of the lectins, with affinities ranging through N-acetylgalactosamine, galactose, N-acetylglucosamine, mannose and sialic acid residues, bound to the cytoplasmic granules of granulated metrial gland cells, and each appeared to bind to the limiting membrane of the granules. The binding characteristics of three of these lectins (Wheat germ agglutinin, Concanavalin A and Helix pomatia agglutinin) were examined using electron microscopical methods. These showed a different binding pattern to the cytoplasmic granules of granulated metrial gland cells compared with that found using light microscopical methods, as they appeared to bind evenly across the granule's matrix. This binding pattern corresponds to the reactivity of the granule matrix in the periodic acid--Schiff technique. Six lectins bound to the cell membranes of granulated metrial gland cells. These included the E and L isoforms of Phaseolus vulgaris agglutinin, with affinities for complex carbohydrates, whose binding differences were related to the stage of differentiation of the granulated metrial gland cells. The lectin binding described presents additional markers of granulated metrial gland cells and tools for investigating carbohydrate moieties in the functional activities of granulated metrial gland cells     

Photolytic binding of the monoazido analog of ethidium to yeast mitochondrial DNA: competition by ethidium.

The [14C]-labeled monoazido analog of ethidium, 3-amino-8-azido-5-ethyl-6-phenylphenanthridinium chloride, when mixed with yeast cells and photolyzed, produced covalent adducts with both nuclear and mitochondrial DNA via the light-generated nitrene. The binding efficiency was about 12 times higher in mitochondrial than nuclear DNA. Moreover, the parent ethidium bromide at a 5-fold excess was an effective competitor for the binding of the monoazide analog with mitochondrial DNA, but not with nuclear DNA.     

Nitrogen fixation by Rhizobium sp. 32H1. A morphological and ultrastructural comparison of asymbiotic and symbiotic nitrogen-fixing forms.

The induction of nitrogenase (C2H2) activity in asymbiotically cultured Rhizobium sp. 32H1 was found to be associated with morphological changes in the cells which were more pronounced than those seen in bacteroids. Polyphosphate granules were found in both bacteroids and cultured cells, but poly-beta-hydroxybutyrate vesicles were almost absent in bacteroids but were present in cultured cells. Freeze-etching techniques revealed no differences between the asymbiotically cultured nitrogen-fixing forms and bacteroids in that both the cell wall and cytoplasmic membrane cleavage planes were normal for gram-negative bacteria.     

Lectin histochemical studies of mouse granulated metrial gland cells

A lectin histochemical study has been carried out on mouse granulated metrial gland cells, the major leucocyte population that differentiates in the uterine wall in pregnancy. The binding characteristics of 26 lectins were examined using light microscopical methods. Fourteen of the lectins, with affinities ranging through N-acetylgalactosamine, galactose, N-acetylglucosamine, mannose and sialic acid residues, bound to the cytoplasmic granules of granulated metrial gland cells, and each appeared to bind to the limiting membrane of the granules. The binding characteristics of three of these lectins (Wheat germ agglutinin, Concanavalin A and Helix pomatia agglutinin) were examined using electron microscopical methods. These showed a different binding pattern to the cytoplasmic granules of granulated metrial gland cells compared with that found using light microscopical methods, as they appeared to bind evenly across the granule's matrix. This binding pattern corresponds to the reactivity of the granule matrix in the periodic acid--Schiff technique. Six lectins bound to the cell membranes of granulated metrial gland cells. These included the E and L isoforms of Phaseolus vulgaris agglutinin, with affinities for complex carbohydrates, whose binding differences were related to the stage of differentiation of the granulated metrial gland cells. The lectin binding described presents additional markers of granulated metrial gland cells and tools for investigating carbohydrate moieties in the functional activities of granulated metrial gland cells This revised version was published online in November 2006 with corrections to the Cover Date.     

Selective inhibition of restriction endonuclease cleavage by DNA intercalators

The preferred dye binding sites and the microenvironment of known nucleotide sequences within mitochondrial and plasmid pBR322 DNA was probed in a gross fashion with restriction endonucleases. The intercalating dyes, ethidium bromide and propidium iodide, do not inhibit a given restriction endonuclease equally at all of the restriction sites within a DNA molecule. The selective inhibition may be explained, in part, by the potential B to Z conformation transition of DNA flanking the restriction site and by preferred dye binding sites. Propidium iodide was found to be a more potent inhibitor than ethidium bromide and the inhibition is independent of the type of cut made by the enzyme.     

Imino 1H- and 31P-NMR analysis of the interaction of propidium and ethidium with DNA

At low temperature and low salt concentration, both imino proton and ³¹p-nmr spectra of DNA complexes with the intercalators ethidium and propidium are in the slow-exchange region. Increasing temperature and/or increasing salt concentration results in an increase in the site exchange rate. Ring-current effects from the intercalated phenanthridinium ring of ethidium and propidium cause upfield shifts of the imino protons of A · T and G · C base pairs, which are quite similar for the two intercalators. The limiting induced chemical shifts for propidium and ethidium at saturation of DNA binding sites are approximately 0.9 ppm for A · T and 1.1 ppm for G · C base pairs. The similarity of the shifts for ethidium and propidium, in both the slow- and fast-exchange regions over the entire titration of DNA, shows that a binding model for propidium with neighbor-exclusion binding and negative ligand cooperativity is correct. The fact that a unique chemical shift is obtained for imino protons at intercalated sites over the entire titration and that no unshifted imino proton peaks remain at saturation binding of ethidium and propidium supports a neighbor-exclusion binding model with intercalators bound at alternating sites rather than in clusters on the double helix. Addition of ethidium and propidium to DNA results in downfield shifts in ³¹P-nmr spectra. At saturation ratios of intercalator to DNA base pairs in the titration, a downfield shoulder (approximately ?2.7 ppm) is apparent, which accounts for approximately 15% of the spectral area. The main peak is at ?3.9 to ?4.0 ppm relative to ?4.35 in uncomplexed DNA. The simplest neighbor-binding model predicts a downfield peak with approximately 50% of the spectral area and an upfield peak, near the chemical shift for uncomplexed DNA, with 50% of the area. This is definitely not the case with these intercalators. The observed chemical shifts and areas for the DNA complexes can be explained by models, for example, that involve spreading the intercalation-induced unwinding of the double helix over several base pairs and/or a DNA sequence- and conformation-dependent heterogeneity in intercalation-induced chemical shifts and resulting exchange rates.     

Fate during cell growth of yeast mitochondrial and nuclear DNA after photolytic attachment of the monoazide analog of ethidium.

The ¹⁴C-labeled photosensitive monoazide analog of ethidium, 3-amino-8-azido-5-ethyl-6-phenylphenanthridinium chloride, produced covalent adducts in yeast cells with both nuclear and mitochondrial DNA on photolysis by visible light. With subsequent cultivation in nutrient medium, drug molecules on mitochondrial DNA were removed only through extensive mitochondrial DNA degradation. In contrast, drug attached to nuclear DNA was eliminated with conservation of DNA, presumably through a repair process.     

Control and virus-transformed baby hamster kidney cells resistant to ethidium bromide. II. Membrane properties

Aspects of membrane stucture and functions were studied in ethidium bromide resistant cells. Submitochondrial particles were solubilized and electrophoresed. The gel patterns, representing mitochondiral membrane proteins, demonstrated qualitative and quantitative alterations in mitochondrial preparations derived from virus-transformed cells and ethidium bromide resistant cells as compared to the control cells. The plasma membrane glycoproteins were labelled by the sodium borohydride method. The glycoporteins were released with Triton X-100 and electrophoresed. Fluorograms of the gels demonstratred some marked differences between the ethidium bromide resistant cells and their parental strain. The observed alterations in the membrane glycoproteins did not result in altered glucose transport properties or in the elution patterns of plasma membrane glycopeptides as analyzed by Sephadex G-50 chromatography. Dye uptake and binding studies with intact parental and drug resistant cells and their isolated mitochondria demonstrated no alteration of the membrane permeability or the number of binding sites for ethidium bromide. Similar results were also obtained with a cyanine dye. This latter finding was significant in that it permitted one to exclude dye exclusion as a mechanism for ethidium bromide resistance.     

Yeast mitochondrial inner membrane 30 kd hydrophobic protein: properties and interaction with phospholipids

A 30 kd hydrophobic protein is extracted from yeast mitochondrial inner membrane. It is present in wild yeast strains but absent in mitochondrial DNA lacking mutants. The isoelectric point of the protein and its solubility in various organic solvents are determined. The fluorescence of a tryptophan residue near the surface of the 30 kd protein dissolved in butanol-1, can be quenched by phospholipids containing unsaturated fatty acids. Results are in accordance with the 30 kd protein being an integral protein of the yeast mitochondrial inner membrane.     

OBSERVATIONS ON THE FINE STRUCTURE OF SPHEROPLASTS OF RHODOSPIRILLUM RUBRUM

Spheroplasts of the photosynthetic bacterium Rhodospirillum rubrum were prepared from cultures grown in either the presence or absence of light. Cells were converted into spheroplasts by using lysozyme and Versene and fixed in a sucrose-veronal-acetate buffer mixture containing osmium tetroxide. Some preparations were shadow-cast and examined whole; others were embedded in Epon 812 and sectioned. The action of lysozyme and Versene appears to result in removal of the cell wall in strips. The relationship of the chromatophores to the cytoplasmic membrane is readily visualized in sections of broken spheroplasts, and in areas the chromatophores are seen to be continuous with the membrane. In all preparations examined, no definite connections between individual chromatophores were observed. In some cells large spherical granules were evident which either possessed or lacked a clearly visible limiting membrane. On serial sectioning, all granules appeared bounded by a single membrane 40 A wide. The granule membrane was well defined only if the section came from the center of the granule. Sections at other levels showed either a diffuse membrane or no membrane at all. The reasons for this are discussed.     

Yeast mutants resistant to ethidium bromide

Summary Yeast mutants resistant to ethidium bromide have been isolated among sensitive grande cells (⁺) for their ability to grow on glycerol in the presence of the dye. Mutant cells are also resistant to acriflavin and do not yield petites (^-) when grown on galactose with the mutagen. Genetic analysis reveals that resistance to ethidium bromide is controlled by a cytoplasmic factor, carried by, or linked to, the determinant (mitochondrial DNA). The expression of resistance to ethidium bromide seems to be related to the presence in the cell of a product of mitochondrial protein synthesis. It is concluded that some mitochondrial DNA sequence is involved in the resistance to ethidium bromide of yeast mitochondria.     

Biogenesis of mitochondria

Summary The action of ethidium bromide and berenil on the mitochondrial genome of Saccharomyces cerevisiae has been compared in three types of study: (i) early kinetics (up to 4 h) of petite induction by the drugs in the presence or absence of sodium dodecyl sulphate; (ii) genetic consequences of long-term (8 cell generations) exposure to the drugs; (iii) inhibition of mitochondrial DNA replication, both in whole cells and in isolated mitochondria.The results have been interpreted as follows. Firstly, the early events in petite induction differ markedly for the two drugs, as indicated by differences in the short-term kinetics. After some stage a common pathway is apparently followed because the composition of the population of petite cells induced after long-term exposure are very similar for both ethidium bromide and berenil. Secondly, both drugs probably act at the same site to inhibit mitochondrial DNA replication, in view of the fact that a petite strain known to be resistant to ethidium bromide inhibition of mitochondrial DNA replication was found to have simultaneously acquired resistance to berenil. From consideration of the drug concentrations needed to inhibit mitochondrial DNA replication in vivo and in vitro it is suggested that in vivo permeability barriers impede the access of ethidium bromide to the site of inhibition of mitochondrial DNA replication, whilst access of berenil to this site is facilitated. The site at which the drugs act to inhibit mitochondrial DNA replication may be different from the site(s) involved in early petite induction. Binding of the drugs at the latter site(s) is considered to initiate a series of events leading to the fragmentation of yeast mitochondrial DNA and petite induction.     

The binding of polyamines and of ethidium bromide to tRNA.

The binding of spermidine and ethidium bromide to mixed tRNA and phenylalanine tRNA has been studied under equilibrium conditions. The numbers and classes of binding sites obtained have been compared to those found in complexes isolated by gel filtration a low ionic strength. The latter complexes contain 10-11 moles of either spermidine or ethidium per mole of tRNA; either cation is completely displaceable by the other. In ethidium complexes, the first 2-3 moles are bound in fluorescent binding sites; the remaining 7-8 molecules bind in non-fluorescent form. At least one of the binding sites for spermidine appears similar to a binding site for fluorescent ethidium. Similar results are found with E. coli formylmethionine tRNA. Spermine, in excess of 18-20 moles per mole tRNA, causes precipitation of the complex. Putrescine does not form isolable complexes with yeast tRNA and displaces ethidium less readily from preformed ethidium-tRNA complexes. Under equilibrium conditions, in the absence of Mg++, there are 16-17 moles of spermidine bound per mole of tRNA as determined by equilibrium dialysis. Of these, 2-3 bind with a Ksence of 9 mM Mg++, the total number of binding sites is decreased slightly and there appears to be only one class of sites with a Ka = 600 M(-1). Quantitatively similar results are obtained for the binding of spermidine to yeast phenylalanine tRNA. When the interaction between ethidium bromide and mixed tRNA is studied by equilibrium dialysis or spectrophotometric titration, two classes of binding sites are obtained: 2-3 molecules bind with an average Ka = 6.6 x 10(5) M(-1) and 14-15 molecules bind with an average Ka = 4.1 x 10(4) M(-1). Spermidine, spermine, and Mg++ compete effectively for both classes of ethidium sites and have the effect of reducing the apparent binding constants for ethidium. When the binding of ethidium is studied by fluorometry, there are 3-4 highly fluorescent sites per tRNA. These sites are also affected by spermidine, spermine and Mg++. Putrescine has little effect on any of the classes of binding sites. These data are consistent with those found under non-equilibrium conditions. They suggest that polyamines bind to fairly specific regions of tRNA and may be involved in the maintenance of certain structural features of tRNA.     

Zygocin,a secreted antifungal toxin of the yeast Zygosaccharomyces bailii,and its effect on sensitive fungal cells

Zygocin, a protein toxin produced and secreted by a killer virus-infected strain of the osmotolerant yeast Zygosaccharomyces bailii, kills a great variety of human and phytopathogenic yeasts and filamentous fungi. Toxicity of the viral toxin is envisaged in a two-step receptor-mediated process in which the toxin interacts with cell surface receptors at the level of the cell wall and the plasma membrane. Zygocin receptors were isolated and partially purified from the yeast cell wall mannoprotein fraction and could be successfully used as biospecific ligand for efficient one-step purification of the 10-kDa protein toxin by receptor-mediated affinity chromatography. Evidence is presented that zygocin-treated yeast cells are rapidly killed by the toxin, and intensive propidium iodide staining of zygocin-treated cells indicated that the toxin is affecting cytoplasmic membrane function, most probably by lethal ion channel formation. The presented findings suggest that zygocin has potential as a novel antimycotic in combating fungal infections.     

pH-dependent influence of a quaternary ammonium salt and an aminoester on the yeast Saccharomyces cerevisiae ultrastructure

Quaternary ammonium salts inhibited the growth of yeast especially at pH higher (pH 8) than optimal. It was postulated that compounds integrate with the cell membrane and interfere with its functions. The yeast cell ultrastructure investigated under an electron microscope confirms this hypothesis. A relatively high percentage of cells treated at pH 6 with the quaternary ammonium salt of alanine derivative (DMALM-12) at the minimal inhibitory concentration showed an irregularity in the cell shape. No such irregularity was observed in the control. Besides, in the cells treated with the drug, practically no lipid droplets were seen at all. Inside the control cells, electron-dense round bodies were clearly seen and interpreted as vacuoles. These bodies were absent in the cells treated with DMALM-12. Although the yeast cells growing at pH 8 showed a more or less normal shape, they seemed to have difficulty in budding - no fully developed buds were found in the preparations. Only some convexities of the cell wall were seen that could be the beginning of budding which stopped early after the start. Some changes in the round bodies interpreted as vacuoles were visible: they were less dense and full of granules.     

MIT-23: A mitochondrial marker for terminal neuronal differentiation defined by a monoclonal antibody

We describe a monoclonal antibody directed against a neuron-specific mitochondrial protein from rat brain. On protein blots the antibody recognizes a single polypeptide of apparent molecular weight 23,000. By solid-phase immunoassay the antigen was detected in all brain regions tested but was not detected in nonneural tissues. Within neurons, the antibody stains cytoplasmic granules that immunoelectron microscopy shows are mitochondria, hence the designation MIT-23. Immunocytochemical staining of the cerebellar cortex showed that MIT-23 occurs in all the neuronal types but is absent from glial and other nonneuronal cells. During neonatal development of the cerebellum, MIT-23 appears in neurons after their final cell division or migration is completed, suggesting that specific proteins associated with mitochondria participate in neuronal maturation.