MMS induction of different types of genetic damage in Aspergillus nidulans: a comparative analysis in mutagenesis.

Methyl methanesulphonate (MMS) was used to test the induction of gene mutation, somatic crossing-over and mitotic non-disjunction in A. nidulans. Gene mutation was tested by inducing mutants resistant to 8-azaguanine and revertants of methG1 in a haploid strain. Somatic crossing-over was tested in heterozygous diploids, both with a selective method, i.e. inducing homozygosis to FPA resistance in a heterozygous fpa A1/+ strain, and with a non-selective method, i.e. identifying the frequencies of colour sectors. This latter method was also used to estimate the induction of non-disjunction because additional markers were present which permitted us to distinguish the two types of colour segregant. Generally, 3 different experimental procedures were used, namely the "plate test", i.e. plating of conidia in agar media containing MMS, and two types of "liquid test", i.e. brief treatment of quiescent or pre-germinated conidia in MMS solution before they were plated on agar media. Point mutations were induced with about equal efficiency with each method, whereas crossing-over was induced preferentially when germinating conidia were exposed to MMS. On the other hand, non-disjunction was induced in germinating and quiescent spores with equal efficiency, but such segregants were not recovered with the selective (fpa) method. The results are discussed for both their practical use in the mutagenic testing procedure and their theoretical implication.     

Oxidation reactions catalyzed by vanadium chloroperoxidase from Curvularia inaequalis

Vanadium haloperoxidases have been reported to mediate the oxidation of halides to hypohalous acid and the sulfoxidation of organic sulfides to the corresponding sulfoxides in the presence of hydrogen peroxide. However, traditional heme peroxidase substrates were reported not to be oxidized by vanadium haloperoxidases. Surprisingly, we have now found that the recombinant vanadium chloroperoxidase from the fungus Curvularia inaequalis catalyzes the oxidation of 2,2'-azino-bis(3-ethylbenzthiazoline-6-sulfonic acid) (ABTS), a classical chromogenic heme peroxidase substrate. The enzyme mediates the oxidation of ABTS in the presence of hydrogen peroxide with a turnover frequency of 11 s(-1) at its pH optimum of 4.0. The Km of the recombinant enzyme for ABTS was observed to be approximately 35 microM at this pH value. In addition, the bleaching of an industrial sulfonated azo dye, Chicago Sky Blue 6B, catalyzed by the recombinant vanadium chloroperoxidase in the presence of hydrogen peroxide is reported.     

Enzymatic bromination of the thiazole ring

Bromination of the thiazole ring by the enzyme chloroperoxidase, produced by the fungus Caldariomyces fumago, was demonstrated. Both 2-acetoacetamido-4-methylthiazole and 2-acetamidothiazole were brominated on C-5 of the thiazole ring in the presence of chloroperoxidase, bromide, and hydrogen peroxide in 0.06 M Phosphate solution at pH 3.0. No reaction occurred in the absence of enzyme.     

Examining the role of glutamic acid 183 in chloroperoxidase catalysis

Site-directed mutagenesis has been used to investigate the role of glutamic acid 183 in chloroperoxidase catalysis. Based on the x-ray crystallographic structure of chloroperoxidase, Glu-183 is postulated to function on distal side of the heme prosthetic group as an acid-base catalyst in facilitating the reaction between the peroxidase and hydrogen peroxide with the formation of Compound I. In contrast, the other members of the heme peroxidase family use a histidine residue in this role. Plasmids have now been constructed in which the codon for Glu-183 is replaced with a histidine codon. The mutant recombinant gene has been expressed in Aspergillus niger. An analysis of the produced mutant gene shows that the substitution of Glu-183 with a His residue is detrimental to the chlorination and dismutation activity of chloroperoxidase. The activity is reduced by 85 and 50% of wild type activity, respectively. However, quite unexpectedly, the epoxidation activity of the mutant enzyme is significantly enhanced approximately 2.5-fold. These results show that Glu-183 is important but not essential for the chlorination activity of chloroperoxidase. It is possible that the increased epoxidation of the mutant enzyme is based on an increase in the hydrophobicity of the active site.     

Potential of animal myeloperoxidase to protect plants from pathogens.

The effect of animal myeloperoxidase (EC 1.11.1.7) on the viability of a plant pathogen was determined. Lethality of hydrogen peroxide to germinating spores of Aspergillus flavus increased 90-fold enzymically. Singlet oxygen was present but hypochlorite accounted for two-thirds of the increase. The results indicate myeloperoxidase could improve microbial resistance in plants, perhaps transgenically.     

Spectra of chloroperoxidase compounds II and III

Chloroperoxidase was present as Compound II during the peroxidatic oxidation of ascorbic acid. Compound III (oxy-form) was formed when excess hydrogen peroxide was added to Compound II. By decreasing the temperature it was possible to measure the spectra of Compounds II and III in the Soret and visible regions. Each spectrum was found to resemble that of the corresponding form of lactoperoxidase. Under the experimental conditions, chloroperoxidase Compound III was apparently converted to Compound II in parallel with the decomposition of hydrogen peroxide and finally to the ferric enzyme.     

Chloroperoxidase-catalyzed halogenation of trans-cinnamic acid and its derivatives

Several 2,3-unsaturated carboxylic acids, such as trans-cinnamic acid and its derivatives, were found to be halogenated by chloroperoxidase of Caldariomyces fumago in the presence of hydrogen peroxide and either Cl- or Br-. Cinnamic acid, 4-hydroxycinnamic acid, 4-methoxycinnamic acid, and 3,4-dimethoxycinnamic acid were suitable substrates of chloroperoxidase, and were converted to 2-halo-3-hydroxycarboxylic acid, 2,3-dihydroxycarboxylic acid, decarboxylated halohydrin, or decarboxylated halocompound. However, 4-nitrocinnamic acid and 4-chlorocinnamic acid having electron-attracting groups did not serve as a substrate of the enzyme. The enzyme also did not act on acrylic acid, acrylamide, crotonic acid, fumaric acid, etc. From these data, the enzymatic reactions of chloroperoxidase, concerning the substrate specificity, stereoselectivity, and the reaction mechanism, are discussed on the basis of current knowledge regarding the reaction mechanism of the enzyme. Also they are compared with the chemical reactions of molecular halogen and hypohalous acid.     

Ribosomes in Dormant and Germinating Conidia of Aspergillus oryzae

Ribosomes were isolated from dormant and germinating conidia of Asp. oryzae No. 13. The ribosomes which consisted of 80 S were easily dissociated into 40 S and 60 S in low Mg^{+ +} buffer. Polyribosomes were not found in dormant conidia, but were found in germinating conidia. Ribosomes in Aspergillus fungi consisted of almost equal amount of RNA and protein, and the base compositions of RNA were alike, as compared as ribosomal RNA between dormant and germinating conidia.     

Molecular and kinetic study of catalase-1, a durable large catalase of Neurospora crassa.

Catalase-1 (Cat-1), one of the two monofunctional catalases of Neurospora crassa, increases during asexual spore formation to constitute 0.6% of total protein in conidia. Cat-1 was purified 170-fold with a yield of 48% from conidiating cultures. Like most monofunctional catalases, Cat-1 is a homotetramer, resistant to inactivation by solvents, fully active over a pH range of 4-12, and inactivated by 3-amino-1,2,4-triazole. Unlike most monofunctional catalases, Cat-1 consists of 88 kDa monomers that are glycosylated with alpha-glucose and/or alpha-mannose, is unusually stable, and is not inactivated or inhibited by hydrogen peroxide. Cat-1 was more resistant than other catalases to heat inactivation and to high concentrations of salt and denaturants. Cat-1 exhibited unusual kinetics: at molar concentrations of hydrogen peroxide the apparent V was 10 times higher than at millimolar concentrations. Inactivation of Cat-1 activity with azide and hydroxylamine was according to first order kinetics, while cyanide at micromolar concentrations was a reversible competitive inhibitor.     

Metabolism of carbon tetrachloride to electrophilic chlorine by liver microsomes: exclusion of cytochrome P-450 catalyzed chloroperoxidase reaction

In this report, we have examined the origin of the electrophilic chlorine formed during the microsomal metabolism of carbon tetrachloride and the possibility that liver microsomal proteins catalyze chloroperoxidase or myeloperoxidase halogenation reactions. Studies with stable isotopes of chlorine show that at least 99% of the trapped chlorine originated from carbon tetrachloride. When hydrogen peroxide or cumene hydroperoxide was added to liver microsomes in the presence of chloride ion, no trapped chlorine was observed. Thus, cytochrome P-450 does not catalyze chloroperoxidase type chloride ion oxidation but instead catalyzes a reaction leading to cleavage of a carbon-chlorine bond with concomitant chlorine atom oxidation.     

The polyene antimycotics nystatin and filipin disrupt the plasma membrane, whereas natamycin inhibits endocytosis in germinating conidia of Penicillium discolor

Aims:  To investigate the differences in membrane permeability and the effect on endocytosis of the polyene antimycotics nystatin, filipin and natamycin on germinating fungal conidia.
Methods and Results:  The model system was Penicillium discolor , a food spoilage fungus. Filipin resulted in permeabilization of germinating conidia for the fluorescent probes TOTO-1 and FM4-64, but not for ferricyanide ions. Nystatin caused influx of all these compounds while natamycin did not. Untreated germinating conidia internalize the endocytic marker FM4-64. Pretreatment of germinating conidia with natamycin showed a dose and time dependent inhibition of endocytosis as judged by the lack of formation of early endosomal compartments.
Conclusions:  The results obtained from this study indicated that, unlike nystatin and filipin, natamycin is unable to permeabilize germinating conidia, but interferes with endocytosis in a dose and time dependent manner.
Significance and Impact of the Study:  Natamycin acts via a different mode of action than other polyene antimycotics. These results offer useful information for new strategies to prevent fungal spoilage on food products and infection on agricultural crops. For laboratory use, natamycin can be used as a specific inhibitor of early endocytosis in fungal cells.     

Chloroperoxidase-catalyzed chlorination of didechloroaglucovancomycin and vancomycin

The chloroperoxidase (CPO) from Caldariomyces fumago catalyzed the chlorination of didechloroaglucovancomycin and vancomycin in the presence of hydrogen peroxide and chloride ion. Chlorination of didechloroaglucovancomycin has afforded new derivatives, with one and two chlorine atoms attached onto the aromatic ring of residue 7 of didechloroaglucovancomycin. Vancomycin was similarly chlorinated under the same conditions to furnish a new dichloro derivative.     

Aspergillus fumigatus triggers inflammatory responses by stage-specific beta-glucan display

Inhalation of fungal spores (conidia) occurs commonly and, in specific circumstances, can result in invasive disease. We investigated the murine inflammatory response to conidia of Aspergillus fumigatus, the most common invasive mold in immunocompromised hosts. In contrast to dormant spores, germinating conidia induce neutrophil recruitment to the airways and TNF-alpha/MIP-2 secretion by alveolar macrophages. Fungal beta-glucans act as a trigger for the induction of these inflammatory responses through their time-dependent exposure on the surface of germinating conidia. Dectin-1, an innate immune receptor that recognizes fungal beta-glucans, is recruited in vivo to alveolar macrophage phagosomes that have internalized conidia with exposed beta-glucans. Antibody-mediated blockade of Dectin-1 partially inhibits TNF-alpha/MIP-2 induction by metabolically active conidia. TLR-2- and MyD88-mediated signals provide an additive contribution to macrophage activation by germinating conidia. Selective responsiveness to germinating conidia provides the innate immune system with a mechanism to restrict inflammatory responses to metabolically active, potentially invasive fungal spores.     

Spin trapping of the azidyl radical in azide/catalase/H2O2 and various azide/peroxidase/H2O2 peroxidizing systems

The azidyl radical is formed during the oxidation of sodium azide by the catalase/hydrogen peroxide system, as detected by the ESR spin-trapping technique. The oxidation of azide by horseradish peroxidase, chloroperoxidase, lactoperoxidase, and myeloperoxidase also forms azidyl radical. It is suggested that the evolution of nitrogen gas and nitrogen oxides reported in the azide/catalase/hydrogen peroxide system results from reactions of the azidyl radical. The azide/horseradish peroxidase/hydrogen peroxide system consumes oxygen, and this oxygen uptake is inhibited by the spin trap 5,5-dimethyl-1-pyrroline-N-oxide, presumably due to the competition with oxygen for the azidyl radical. Although azide is used routinely as an inhibitor of myeloperoxidase and catalase, some consideration should be given to the biochemical consequences of the formation of the highly reactive azidyl radical by the peroxidase activity of these enzymes.     

Bromine derivatives of amino acids as intermediates in the peroxidase-catalyzed formation of singlet oxygen

Recently, J. R. Kanofsky et al. (1988, J. Biol. Chem. 263, 9692-9696) reported that human eosinophils generated modest amounts of singlet oxygen. In the mechanism proposed, hypobromous acid (made from the peroxidase-catalyzed oxidation of bromide ion) reacted with hydrogen peroxide to form singlet oxygen. In contrast, human neutrophils, which generate both hypochlorous acid and hydrogen peroxide, do not make singlet oxygen. The failure of human neutrophils to generate singlet oxygen is due in part to the trapping of hypochlorous acid by endogenous amines. In this paper, I show that amino acids are much more effective traps for hypochlorous acid than for hypobromous acid. Glycine totally inhibits singlet oxygen generation from a model enzyme system composed of chloroperoxidase, hydrogen peroxide, and chloride ion, but causes only a 35% reduction in singlet oxygen generation from an analogous enzyme system containing bromide ion instead of chloride ion. The products of the reaction of hypobromous and glycine (presumably an equilibrium mixture of N-bromoglycine, N,N-dibromoglycine, and hypobromous acid) retain the ability to react with hydrogen peroxide to form singlet oxygen. In contrast, the products of the reaction of hypochlorous acid and glycine do not react with hydrogen peroxide to produce singlet oxygen. Similar results were obtained for L-alanine, L-arginine, L-asparagine, L-aspartic acid, L-cystine, L-glutamic acid, L-glutamine, L-histidine, L-lysine, L-phenylalanine, L-proline, L-serine, and L-tyrosine. Thus, bromine derivatives of amino acids may act as intermediates in the peroxidase-catalyzed generation of singlet oxygen.     

Chemical reactivities of bleomycin

Ferric bleomycin was tested for its ability to catalyze a set of six oxidative reactions characteristic of the heme-containing proteins, cytochrome P-450 and chloroperoxidase. These reactions included peroxyacid decarboxylation and aliphatic hydroxylation as typical cytochrome P-450 chemistries. Peroxyacid-supported oxygen evolution and hydrogen peroxide-mediated chlorination were utilized as characteristic chloroperoxidase reactivities. A typical peroxidative reaction and heteroatom dealkylation, common to both O2 activating enzymes, were also studied. Bleomycin was found to catalyze peroxidation of o-dianisidine. The ferric drug complex was found competent in carrying out N-demethylation of N,N-dimethylaniline when peroxides or peroxyacids or iodosobenzene were used as the oxidants. N-Demethylation was not achieved when N,N-dimethylaniline-N-oxide was substituted as the oxidant under similar conditions. Hydroxylation of cumene and decarboxylation of phenylperacetic acid were not found to be catalyzed by bleomycin. Oxygen evolution from m-chloroperbenzoic acid and chlorination of monochlorodimedone from chloride ion and hydrogen peroxide were found to be catalyzed by bleomycin. Cytochrome P-450cam was also evaluated for O2 evolution, and halogenation activity and was found not to demonstrate such reactivities. The results of this initial survey, along with those of previous studies, appear to indicate that the chemical reactivity of bleomycin can be more closely aligned with the reactivities demonstrated by chloroperoxidase than those of cytochrome P-450.     

Reactive oxygen species generation and peroxidase activity during Oidium neolycopersici infection on Lycopersicon species.

Histochemical and biochemical study of plant tissue responses were carried out on three Lycopersicon spp. accessions differing in response to Oidium neolycopersici. High production of superoxide anion was observed mainly in infected leaves of highly susceptible Lycopersicon esculentum cv. 'Amateur' during the first hours post inoculation (hpi). The production of hydrogen peroxide as well as an increase of peroxidase (POX) activity were detected mainly in resistant accessions at 4-12 hpi. A signal confirming the presence of very active POX was found in the apical part of tubes of germinating fungus and inside dead conidia. Increased soluble POX and catalase activity in leaf extracts of resistant accessions L. chmielewskii (LA 2663) and L. hirsutum (LA 2128) (20 hpi) correlated with the percentage of dead cells in infection sites. The correlation between production of reactive oxygen species (ROS) and activity of enzymes participating in their metabolism and hypersensitive response was evident during plant defence response.     

Transformation of Intact Aspergillus niger by Electroporation

A new rapid transformation system for Aspergillus niger that uses electroporation to render intact germinating conidia permeable to DNA is described. The transformant colonies appeared earlier than transformants obtained by the protoplast-forming method. Without pretreatment of the conidia the transformation frequencies were 1.2 colonies per μg of integrative vector and 100 colonies per μg of plasmid DNA. When the conidia were treated with a dilute solution of fungal cell wall lytic enzyme, the frequency of transformation was increased by approx. 2-fold when using two vectors. Southern blot analysis of genomic DNA and restriction endonuclease-digested DNA from a random sample of transformants showed homologous and nonhomologous integration of the integrative vector into the genome, as is also observed with the protoplast-forming method. In transformation with the plasmid vector, the transformant DNA was shown to be mostly maintained in free form with minimal integration into the chromosome when transformed by either intact electroporation or the conventional method.     

Potentiation by L-cysteine of the bactericidal effect of hydrogen peroxide in Escherichia coli.

Under anaerobic conditions an exponentially growing culture of Escherichia coli K-12 was exposed to hydrogen peroxide in the presence of various compounds. Hydrogen peroxide (0.1 mM) together with 0.1 mM L-cysteine or L-cystine killed the organisms more rapidly than 10 mM hydrogen peroxide alone. The exposure of E. coli to hydrogen peroxide in the presence of L-cysteine inhibited some of the catalase. This inhibition, however, could not fully explain the 100-fold increase in hydrogen peroxide sensitivity of the organism in the presence of L-cysteine. Of other compounds tested only some thiols potentiated the bactericidal effect of hydrogen peroxide. These thiols were effective, however, only at concentrations significantly higher than 0.1 mM. The effect of L-cysteine and L-cystine could be annihilated by the metal ion chelating agent 2,2'-bipyridyl. DNA breakage in E. coli K-12 was demonstrated under conditions where the organisms were killed by hydrogen peroxide.