Effect of metal ions in the culture medium on the stearoyl-coenzyme A desaturase activity of Mycobacterium phlei.

A particulate fraction prepared from Mycobacterium phlei grown in a metal-deficient medium exhibited a greatly reduced activity of stearoyl-CoA desaturase compared to that from normally grown cells. Metal deficiency, however, had no effect on the FAD-dependent NADPH-cytochrome C reductase activity, which has been suggested to participate in the desaturation process. When the cells were grown in the deficient medium supplemented with both Fe2+ and Mg2+, the desaturase activity was restored to the normal level. Supplementation with Mg2+ alone promoted growth but did not restore the desaturase activity, whereas Fe2+ alone did cause a significant restoration. Among the various metal ions tested, only Fe2+ and Fe3+ enhanced the formation of desaturase activity in the deficient medium. When added to the assay medium in vitro, Fe2+ and Fe3+ did not stimulate the desaturase activity of the particulate fraction from the deficient cells. Cultivation in the metal-deficient medium had essentially no effect on the levels of cytochromes in the particulate fraction, but dramatically decreased the non-heme iron content and the amount of a high-spin ferric species exhibiting an ESR signal at g=4.3. No labile sulfur could be detected in the normal or metal-deficient particulate fractions. It is concluded that the presence of iron ions in the culture medium is necessary for the synthesis and/or assembly of the terminal portion of the desaturase system.     

Cloning, sequencing, and mutational analysis of the Bradyrhizobium japonicum fumC-like gene: evidence for the existence of two different fumarases.

The Bradyrhizobium japonicum fumarase gene (fumC-like) was cloned and sequenced, and a fumC deletion mutant was constructed. This mutant had a Nod+ Fix+ phenotype in symbiosis with the host plant, soybean, and growth in minimal medium with fumarate as sole carbon source was also not affected. The cloned B. japonicum fumC gene fully complemented an Escherichia coli Fum- mutant, strain JH400, for growth in minimal medium with fumarate. The predicted amino acid sequence of the FumC protein showed strong similarity to the E. coli FumC protein, Bacillus subtilis CitG protein, Saccharomyces cerevisiae Fum1 protein, and the mammalian fumarases. The B. japonicum FumC protein accounted for about 40% of the total fumarase activity in aerobically grown cells. The remaining 60% was ascribed to a temperature-labile fumarase. These data suggest that B. japonicum possesses two different fumarase isoenzymes, one of which is encoded by fumC. Besides E. coli, which has three fumarases, B. japonicum is thus the second bacterium for which there is genetic evidence for the existence of more than one fumarase.     

Purification and characterization of two types of fumarase from Escherichia coli

Two distinct types of fumarase were purified to homogeneity from aerobically grown Escherichia coli W cells. The amino acid sequences of their NH2-terminals suggest that the two enzymes are the products of the fumA gene (FUMA) and fumC gene (FUMC), respectively. FUMA was separated from FUMC by chromatography on a Q-Sepharose column, and was further purified to homogeneity on Alkyl-Superose, Mono Q, and Superose 12 columns. FUMA is a dimer composed of identical subunits (Mr = 60,000). Although the activity of FUMA rapidly decreased during storage, reactivation was attained by anaerobic incubation with Fe2+ and thiols. Studies on the inactivation and reactivation of FUMA suggested that oxidation and the concomitant release of iron inactivated the enzyme in a reversible manner. While the inactivated FUMA was EPR-detectable, through a signal with g perpendicular = 2.02 and g = 2.00, the active enzyme was EPR-silent. These results suggested FUMA is a member of the 4Fe-4S hydratases represented by aconitase. After the separation of FUMC from FUMA, purification of the former enzyme was accomplished by chromatography on Phenyl-Superose and Matrex Gel Red A columns. FUMC was stable, Fe-independent and quite similar to mammalian fumarases in enzymatic properties.     

Copper deprivation potentiates oxidative stress in HL-60 cell mitochondria.

Cytochrome-c oxidase is the copper-dependent terminal respiratory complex (complex IV) of the mitochondrial electron transport chain whose activity in a variety of tissues is lowered by copper deficiency. Because inhibition of respiratory complexes increases the production of reactive oxygen species by mitochondria, it is possible that copper deficiency increases oxidative stress in mitochondria as a consequence of suppressed cytochrome-c oxidase activity. In this study, the activities of respiratory complex I + III, assayed as NADH:cytochrome-c reductase, complex II + III, assayed as succinate:cytochrome-c reductase, complex IV, assayed as cytochrome-c oxidase, and fumarase were measured in mitochondria from HL-60 cells that were grown for seven passages in serum-free medium that was either unsupplemented or supplemented with 50 n M CuSO4. Fumarase activity was not affected by copper supplementation, but the complex I + III:fumarase and complex IV:fumarase ratios were reduced 30% and 50%, respectively, in mitochondria from cells grown in the absence of supplemental copper. This indicates that copper deprivation suppressed the electron transfer activity of copper-independent complex I + III as well as copper-dependent complex IV. Manganese superoxide dismutase (MnSOD) content was also increased 49% overall in the cells grown in the absence of supplemental copper. Furthermore, protein carbonyl groups, indicative of oxidative modification, were present in 100-kDa and 90-kDa proteins of mitochondria from copper-deprived cells. These findings indicate that in cells grown under conditions of copper deprivation that suppress cytochrome-c oxidase activity, oxidative stress in mitochondria is increased sufficiently to induce MnSOD, potentiate protein oxidation, and possibly cause the oxidative inactivation of complex I.     

Mesaconase/Fumarase FumD in Escherichia coli O157:H7 and Promiscuity of Escherichia coli Class I Fumarases FumA and FumB

Mesaconase catalyzes the hydration of mesaconate (methylfumarate) to (S)-citramalate. The enzyme participates in the methylaspartate pathway of glutamate fermentation as well as in the metabolism of various C₅-dicarboxylic acids such as mesaconate or L-threo-β-methylmalate. We have recently shown that Burkholderia xenovorans uses a promiscuous class I fumarase to catalyze this reaction in the course of mesaconate utilization. Here we show that classical Escherichia coli class I fumarases A and B (FumA and FumB) are capable of hydrating mesaconate with 4% (FumA) and 19% (FumB) of the catalytic efficiency k _cat/K _m, compared to the physiological substrate fumarate. Furthermore, the genomes of 14.8% of sequenced Enterobacteriaceae (26.5% of E. coli, 90.6% of E. coli O157:H7 strains) possess an additional class I fumarase homologue which we designated as fumarase D (FumD). All these organisms are (opportunistic) pathogens. fumD is clustered with the key genes for two enzymes of the methylaspartate pathway of glutamate fermentation, glutamate mutase and methylaspartate ammonia lyase, converting glutamate to mesaconate. Heterologously produced FumD was a promiscuous mesaconase/fumarase with a 2- to 3-fold preference for mesaconate over fumarate. Therefore, these bacteria have the genetic potential to convert glutamate to (S)-citramalate, but the further fate of citramalate is still unclear. Our bioinformatic analysis identified several other putative mesaconase genes and revealed that mesaconases probably evolved several times from various class I fumarases independently. Most, if not all iron-dependent fumarases, are capable to catalyze mesaconate hydration.     

Kinetic and spectroscopic studies on the quercetin 2,3-dioxygenase from Bacillus subtilis

Quercetin 2,3-dioxygenase from Bacillus subtilis (QueD) converts the flavonol quercetin and molecular oxygen to 2-protocatechuoylphloroglucinolcarboxylic acid and carbon monoxide. QueD, the only known quercetin 2,3-dioxygenase from a prokaryotic organism, has been described as an Fe2+-dependent bicupin dioxygenase. Metal-substituted QueDs were generated by expressing the enzyme in Escherichia coli grown on minimal media in the presence of a number of divalent metals. The addition of Mn2+, Co2+, and Cu2+ generated active enzymes, but the addition of Zn2+, Fe2+, and Cd2+ did not increase quercetinase activity to any significant level over a control in which no divalent ions were added to the media. The Mn2+- and Co2+-containing QueDs were purified, characterized by metal analysis and EPR spectroscopy, and studied by steady-state kinetics. Mn2+ was found to be incorporated nearly stoichiometrically to the two cupin motifs. The hyperfine coupling constant of the g = 2 signal in the EPR spectra of the Mn2+-containing enzyme showed that the two Mn2+ ions are ligated in an octahedral coordination. The turnover number of this enzyme was found to be in the order of 25 s(-1), nearly 40-fold higher than that of the Fe2+-containing enzyme and similar in magnitude to that of the Cu2+-containing quercertin 2,3-dioxygenase from Aspergillus japonicus. In addition, kinetic and spectroscopic data suggest that the catalytic mechanism of QueD is different from that of the Aspergillus quercetinases but similar to that proposed for the extradiol catechol dioxygenases. This study provides evidence that Mn2+ might be the preferred cofactor for this enzyme and identifies QueD as a new member of the manganese dioxygenase family.     

Characterization of multiple fumarase proteins in Escherichia coli

Two different types of fumarase were found in sonic extracts of Escherichia coli; one required Fe-S for the enzyme activity, and the other did not. When the cells were grown without aeration, the Fe-S-independent enzyme occupied over 80% of the overall fumarase activity. Highly purified Fe-S-independent enzyme was suggested to be composed of four subunits (Mr = 48 kDa) by SDS-polyacrylamide gel electrophoresis and gel filtration. Amino acid and N-terminal sequence analyses supported the possibility that the enzyme is a product of fumC gene (FUMC). In aerobically grown cells, however, the content of FUMC was low and the Fe-S-dependent fumarase occupied over 80% of the overall activity. The Fe-S-dependent enzyme appeared to be labile and the activity was rapidly lost during purification. Although the spontaneous inactivation was previously ascribed to thermal lability (S.A. Woods & J.R. Guest (1987) FEMS Microbiol. Lett. 48, 219), the activity could be restored by anaerobic incubation with ferrous ions and SH-compounds.     

Mesaconase Activity of Class I Fumarase Contributes to Mesaconate Utilization by Burkholderia xenovorans

Pseudomonas aeruginosa, Yersinia pestis, and many other bacteria are able to utilize the C₅-dicarboxylic acid itaconate (methylenesuccinate). Itaconate degradation starts with its activation to itaconyl coenzyme A (itaconyl-CoA), which is further hydrated to (S)-citramalyl-CoA, and citramalyl-CoA is finally cleaved into acetyl-CoA and pyruvate. The xenobiotic-degrading betaproteobacterium Burkholderia xenovorans possesses a P. aeruginosa-like itaconate degradation gene cluster and is able to grow on itaconate and its isomer mesaconate (methylfumarate). Although itaconate degradation proceeds in B. xenovorans in the same way as in P. aeruginosa, the pathway of mesaconate utilization is not known. Here, we show that mesaconate is metabolized through its hydration to (S)-citramalate. The latter compound is then metabolized to acetyl-CoA and pyruvate with the participation of two enzymes of the itaconate degradation pathway, a promiscuous itaconate-CoA transferase able to activate (S)-citramalate in addition to itaconate and (S)-citramalyl-CoA lyase. The first reaction of the pathway, the mesaconate hydratase (mesaconase) reaction, is catalyzed by a class I fumarase. As this enzyme (Bxe_A3136) has similar efficiencies (k_cat/K_m) for both fumarate and mesaconate hydration, we conclude that B. xenovorans class I fumarase is in fact a promiscuous fumarase/mesaconase. This promiscuity is physiologically relevant, as it allows the growth of this bacterium on mesaconate as a sole carbon and energy source.     

Mapping metal ions at the catalytic centres of two intron-encoded endonucleases.

Divalent metal ions play a crucial role in forming the catalytic centres of DNA endonucleases. Substitution of Mg2+ ions by Fe2+ ions in two archaeal intron-encoded homing endonucleases, I-DmoI and I-PorI, yielded functional enzymes and enabled the generation of reactive hydroxyl radicals within the metal ion binding sites. Specific hydroxyl radical-induced cleavage was observed within, and immediately after, two conserved LAGLIDADG motifs in both proteins and at sites at, and near, the scissile phosphates of the corresponding DNA substrates. Titration of Fe2+-containing protein-DNA complexes with Ca2+ ions, which are unable to support endonucleolytic activity, was performed to distinguish between the individual metal ions in the complex. Mutations of single amino acids in this region impaired catalytic activity and caused the preferential loss of a subset of hydroxyl radical cleavages in both the protein and the DNA substrate, suggesting an active role in metal ion coordination for these amino acids. The data indicate that the endonucleases cleave their DNA substrates as monomeric enzymes, and contain a minimum of four divalent metal ions located at or near the catalytic centres of each endonuclease. The metal ions involved in cleaving the coding and the non-coding strand are positioned immediately after the N- and C-terminally located LAGLIDADG motifs, respectively. The dual protein/nucleic acid footprinting approach described here is generally applicable to other protein-nucleic acid complexes when the natural metal ion can be replaced by Fe2+.     

Tetrapyrrole utilization by Bacteroids ruminocola.

Reduced versus oxidized difference spectra of whole cells and pyridine hemochromogens of heme-requiring isolates of Bacteroides ruminicola are altered when deuteroporphyrin or mesoporphyrin replaces protoheme as a growth factor. During growth in the presence of either deuteroporphyrin or mesoporphyrin, whole cells exhibit peaks at 545 t547, 515 to 518, and 412 to 413 nm. Pyridine hemochromogen spectra confirm the presence of meso -or deuteroheme in cells grown in the presence of meso- or deuteroporphyrin. No evidence was found for the conversion of either meso- or deuteroporphyrin to protoheme. Cells grown in the presence of the manganese of magnesium chelates of protoheme form iron-containing hemes. Neither spontaneous decomposition of noniron metalloporphyrin chelates nor spontaneous formation of hemes from Fe2+ and metal-free porphyrins was detected. Protoheme-synthesizing isolates of B. ruminicola fail to use preformed metal-free porphyrins, but form both protoheme- and deuteroheme-containing cytochromes when grown in the presence of manganese deuteroheme. Versatility in tetrapyrrole utilization by B. ruminicola appears to reflect the ability of the organism to mediate the removal of nonferrous ions and to insert Fe2+ into the tetrapyrrole nucleus. The orgamism also forms functional b-type cytochromes with prosthetic groups other than protoheme.     

The cytoplasmic membrane as the site of the antimicrobial action of N-octylethanolamine

On agar spread plates, N-octylethanolamine was biocidal at comparable minimum inhibitory concentration (MIC) values (3–4mm) against Pseudomonas aeruginosa (two strains), Escherichia coli, Staphylococcus aureus, Bacillus subtilis, Candida tropicalis, and Acremonium sp. which had been grown on a number of different media. The inhibition was greater at higher pH values. In liquid culture, growth inhibition by 3mm N-octylethanolamine was accompanied by cell lysis. Both effects could be prevented by the presence of 1mm spermine or spermidine, but only in bacteria, and not at high pH values. These effects of the polyamines were shown to be non-specific, being shared by other polycations and Mg²⁺ ions. N-Octylethanolamine at concentrations above its MIC caused total inhibition of the oxidation of 1mm glucose by Ps. aeruginosa (CAS1 and PAO1), E. coli, or C. tropic an effect that was partially reversible by Mg²⁺ ions. At concentrations below the MIC, there was little inhibit ion of glucose oxidation but a potent inhibition of the extrusion of ethidium bromide from intact cells of E. coli, suggesting that at such concentrations N-octylethanolamine is uncoupling oxidative phosphorylation. The data presented confirm the view that the biocidal effects are due to action on the cytoplasmic membrane.     

Differences in the protein fluorecence of the two iron(III)-binding sites of ovotransferrin.

1. Changes in the tryptophan fluorescence and the visible absorption spectrum resulting from the combination of apo-ovotransferrin with Fe3+, F,E2+, Cu2+, Zn2+, Mn2+, and Cd2+were measured. 2. As expected for a radiationless transfer of electronic excitation energy, only the ions Fe3+, Fe2+and Cu2+, which gave complexes with large extinctions between 300 and 370nm, resulted in large decreases in trytophan fluorescence. 3. The decrease in protein fluorescence was non-linear with increasing occupancy of the Fe3+ -and Cu2+ - binding sites. The decrease in fluorescence on binding of Fe3+ was biphasic and showed that the two metal-binding sites were being occupied sequentially at pH7.4-8.4. The first site reacted with Fe3+ instantaneously, the second was occupied over a minute. 5. The nonidentity of the two sites was also demonstrated by the preparation of a stable hybrid containing both Cu2+ and Zn2+.h Cu2+ and Zn2+     

The presence of two proteinases associated with the cell wall of Lactobacillus bulgaricus

Abstract Whole cells of Lactobacillus delbrueckii subsp. bulgaricus ACA DC235 are able to hydrolyse casein. This proteolytic activity is greatly enhanced when cells are grown in milk rather than in a peptide-rich synthetic medium such as De Man-Sharp-Rogosa. A significant part of the caseinolytic activity can be extracted by treating the intact cells with lysozyme, which suggests that the enzyme(s) involved are associated with the cell wall. The soluble lysozyme extract has been partially fractionated by ultrafiltration using different membranes. Biphasic kinetics of irreversible thermal denaturation, partial inactivation by various agents, and selective reactivation by zinc ions indicated that the overall caseinolytic activity was due to two distinct enzymes. The first one was rapidly inactivated upon heating, inhibited by EDTA, reactivated by Zn²⁺ ions, and was probably a zinc-dependent metalloprotease. The other one was more stable towards thermal inactivation, inhibited by phenylmethanesulfonyl fluoride, insensitive to N -ethylmaleimide, activated by Ca2+ ions, and was probably a serine protease.     

Different metal-binding properties of the two sites of human transferrin.

Transferrin, the serum serum iron-transport protein which can bind two metal ions at physiologic pH, binds just one Fe3+, VO2+, or Cr3+ ion at pH 6.0. Fe3+ and VO2+ appear to be bound at the same site, designated A, based on electron paramagnetic resonance (EPR) spectra of VO2+-transferrin and (Fe3+)1(VO2+)1-transferrin. The EPR spectra of (Cr3+)1(VO2+)1-transferrin and of (Cr3+), (FE3+)1-transferrin indicate that that Cr3+ is bound to site B at pH 6.0. Transferrin was labeled at site A with 59Fe at pH 6.0 and at site B with 55Fe at pH 7.5. When the pH of the resulting preparation was lowered to 6.3 and the dissociated iron was separated by gel filtration, about ten times as much 55Fe as 59Fe was lost. The same EPR and isotopic-labeling experiments showed that Fe3+ added to transferrin at pH 7.5 binds to site A with about 90% selectivity.     

Different cellular targets for Cu- and Fe-catalyzed oxidation observed using a Cu-compatible thiobarbituric acid assay

The widely used thiobarbituric acid (TBA) assay for oxidative damage to biomolecules fails in Cu2(+)-containing solutions due to the formation of a cloudy precipitate. The chelation of Cu2+ ions with EDTA or Chelex was investigated. Both prevented precipitate formation, but only Chelex allowed proper color development in the TBA assay. The Chelex modified assay could be adapted to a variety of systems, and was applied to the detection of Cu2+/ascorbate dependent deoxyribose breakdown and oxidative damage in erythrocyte ghosts, lysates and whole cells. Using this method, it was shown that Cu2+/ascorbate caused membrane damage in ghosts but not in whole red blood cells (RBC). Fe3+/ascorbate, on the other hand, caused formation of TBA-reactive products even in whole RBC. When Cu2+ and Fe3+ were presented to isolated hemoglobin as their 1:1 nitrilotriacetate complexes, the protein bound 10-12 cupric ions per molecule, but no ferric ions. It is suggested that oxidative damage catalyzed by copper or iron ions has different cellular targets, determined by the different binding properties of the two metals to various cellular components.     

Fe2+ binding to apo and holo mammalian ferritin

The binding of Fe2+ to both apo and holo mammalian ferritin has been investigated under anaerobic conditions as a function of pH. In the pH range 6.0-7.5, 8.0 +/- 0.5 Fe2+ ions bind to each apoferritin molecule, but above pH 7.5, a pH-dependent Fe2+ binding profile is observed with up to 80 Fe2+ ions binding at pH 10.0. This Fe2+ binding is reversible and is accompanied by up to two H+ being released per Fe2+ bound at pH 10.0. The Fe2+ binding to apoferritin probably occurs in the 3-fold channels. A much larger and more complex pH-dependent Fe2+ binding stoichiometry was observed for holoferritin with up to 300 Fe2+ ions binding at pH 10.0. This pH-dependent Fe2+ binding was interpreted as Fe2+ interaction at the FeOOH mineral surface with displacement of H+ from -OH or phosphate surface groups by the incoming Fe2+ ions. Mossbauer spectroscopic measurements using 57Fe-labeled Fe2+ under anaerobic conditions showed that 57Fe2+ binding to holoferritin was accompanied by electron transfer to the core, yielding 57Fe3+, presumably bound to the mineral surface. Removal of added iron by Fe2+-specific chelating agents yielded 57Fe2+, demonstrating the reversibility of this electron-transfer process. The Fe2+ bound to apo- and holoferritin is readily converted to Fe3+ by exposure to O2 and strongly retained by the respective ferritin species.     

The role of iron in the activation of mannonic and altronic acid hydratases, two Fe-requiring hydro-lyases

D-Altronate hydratase and D-mannonate hydratase belong to a class of Fe2+-requiring enzymes, but the function of iron in these enzymes is largely unknown. Methods are described for the convenient preparation of both these hydratases from Escherichia coli and studies related to metal activation are presented. The enzymes are inactive in the absence of a bivalent metal and a reducing agent such as dithiothreitol. Fe2+ at low concentrations activates the enzymes efficiently, but inhibits them over 2 mM. Furthermore Mn2+ is also capable of activating aldonic acid hydratases and appears to be a constituent of the enzyme active center. A marked synergistic activation is observed in the presence of both ions, raising the possibility that the enzyme has two binding sites for ions. Upon activation, the two aldonic acid hydratases incorporate a single Fe atom and contain no Fe-S core, in contrast to other characterized Fe-hydratases, such as aconitase or maleic acid hydratase. The incorporated iron is losely bound (with Kd about 4.5 mM and 20 mM for mannonate and altronate hydratase, respectively) and can be readily removed with EDTA. The enzymes exhibit no requirement for sulphide ions and are insensitive to thiol reagents. A first-order inhibition is observed with iron chelators and can be removed by competition with excess metal ions. No change in the absorption spectra is observed upon oxidation-reduction or activation with metals. The activated enzymes exhibit no electron paramagnetic (EPR) spectrum under anaerobic conditions; in the presence of oxygen, an intense EPR spectrum develops in Fe2+-activated samples with signal at g = 1.98, which upon reaction of the enzyme with the substrate moves into a species with signals at g = 4.15 and g = 9.07, with EPR parameters very similar to those of oxidized rubredoxins.     

Rhodobacter capsulatus CycH: a bipartite gene product with pleiotropic effects on the biogenesis of structurally different c-type cytochromes.

While searching for components of the soluble electron carrier (cytochrome c2)-independent photosynthetic (Ps) growth pathway in Rhodobacter capsulatus, a Ps- mutant (FJM13) was isolated from a Ps+ cytochrome c2-strain. This mutant could be complemented to Ps+ growth by cycA encoding the soluble cytochrome c2 but was unable to produce several c-type cytochromes. Only cytochrome c1 of the cytochrome bc1 complex was present in FJM13 cells grown on enriched medium, while cells grown on minimal medium contained at various levels all c-type cytochromes, including the membrane-bound electron carrier cytochrome cy. Complementation of FJM13 by a chromosomal library lacking cycA yielded a DNA fragment which also complemented a previously described Ps- mutant, MT113, known to lack all c-type cytochromes. Deletion and DNA sequence analyses revealed an open reading frame homologous to cycH, involved in cytochrome c biogenesis. The cycH gene product (CycH) is predicted to be a bipartite protein with membrane-associated amino-terminal (CycH1) and periplasmic carboxyl-terminal (CycH2) subdomains. Mutations eliminating CyCH drastically decrease the production or all known c-type cytochromes. However, mutations truncating only its CycH2 subdomain always produce cytochrome c1 and affect the presence of other cytochromes to different degrees in a growth medium-dependent manner. Thus, the subdomain CycH1 is sufficient for the proper maturation of cytochrome c1 which is the only known c-type cytochrome anchored to the cytoplasmic membrane by its carboxyl terminus, while CycH2 is required for efficient biogenesis of other c-type cytochromes. These findings demonstrate that the two subdomains of CycH play different roles in the biogenesis of topologically distinct c-type cytochromes and reconcile the apparently conflicting data previously obtained for other species.     

Physicochemical characterization of the microbial Fe2+ chelator proferrorosamine from Pseudomonas roseus fluorescens.

The microbial chelating compound proferrorosamine A, produced by Pseudomonas roseus fluorescens, formed a complex with Fe2+ of which the apparent stability constant was found to be 10(23). The following order of increasing stability constants of metal complexes with proferrorosamine was established as: Ba2+, Ca2+, Mg2+, Mn2+ less than Hg2+ less than Zn2+ less than Pb2+ less than Co2+ less than Cu2+ congruent to Fe2+ less than Ni2+. Only Ni(2+)-proferrorosamine had a stability constant which was established as: Ba2+, Ca2+, Mg2+, Mn2+ less than Hg2+ less than Zn2+ less than Pb2+ less than Co2+ less than Cu2+ congruent to Fe2+ less than Ni2+. Only Ni(2+)-proferrorosamine had a stability constant which was ca 32 times higher than Fe(2+)-proferrorosamine. Because of the production of proferrorosamine the growth of Ps. roseus fluorescens was not inhibited in iron limiting media by the addition of 0.15 mmol/l of the weaker chemical Fe2+ chelator 2,2'-dipyridyl. This contrasted with the proferrorosamine-negative mutant K2 and Ps. stutzeri, which only produces Fe(3+)-chelating siderophores. Furthermore, it was found that proferrorosamine was able to dissolve Fe2+ from stainless steel. These results show that proferrorosamine is a strong and selective Fe2+ chelator which could be used as an alternative for the toxic 2,2'-dipyridyl to control lactic acid fermentations.     

Transfecting activity of Pseudomonas aeruginosa bacteriophage SM

Factors affecting the efficiency of transfection of Ps. aeruginosa PAO1 cells by the temperate SM bacteriophage DNA have been determined. The efficiency of transfection by DNA preparations isolated from the wild type bacteriophage SMc+ or its thermoinducible mutant SM cts6 is practically the same. The frequency of transfection is (7-9) X 10(4) of infectious centers per mkg of transfecting DNA. Variability in the frequencies of transfection has been registered depending of the infection conditions or on the transfer of the Ps. aeruginosa PAO1 recipient strain population into the competence phase. The efficiency of transfection is increased by the addition of Ca2+ or Mg2+ ions affecting the adsorption and absorbtion of phage DNA by the recipient cells. Optimal concentrations of the bivalent metal ions are 0.15M CaCl2 and 0.2M MgCl2. The results obtained have been used for optimizing the conditions of Ps. aeruginosa PAO1 transfection by SM bacteriophage DNA.