Manganese and defenses against oxygen toxicity in Lactobacillus plantarum

Superoxide dismutase and oxygen toxicity defenses in the genus Neisseria

Among aerotolerant cells, Neisseria gonorrhoeae is very unusual because despite its obligately aerobic lifestyle and frequent isolation from purulent exudates containing polymorphonuclear leukocytes vigorously evolving O2- and H2O2, it contains no superoxide dismutase (SOD). Strains (14) of N. gonorrhoeae were compared with each other and with strains of Neisseria meningitidis, Neisseria mucosa, and Neisseria subflava under identical growth conditions for their contents of the oxy-protective enzymes catalase, peroxidase, and SOD, as well as respiratory chain proteins and activity. The absence of SOD from N. gonorrhoeae strains was demonstrated under a variety of oxygen-stress conditions. The neisserial species showed very different SOD, catalase, and peroxidase profiles. These profiles correlated well with the tolerance of the species to various intra- and extracellular oxygen insults. The high tolerance of N. gonorrhoeae for extracellular O2- and H2O2 appeared to be due to very high constitutive levels of peroxidase and catalase activity combined with a cell envelope impervious to O2-. Nevertheless, N. gonorrhoeae 19424 was much more sensitive to an intracellular flux of O2- than were the other (SOD-containing) neisserial species. The responses of N. gonorrhoeae and N. meningitidis respiratory and oxy-protective enzymes to growth under high and low oxygen tensions were followed, and a novel response, the apparent repression of the respiratory chain intermediates, respiration, and SOD, peroxidase, and catalase activity, was observed. The gonococcal catalase was partially purified and characterized. The results suggest that the very active terminal oxidase, low pO2 natural habitat, O2-stable catalase, and possibly the high glutathione content of the organism explain its aerobic survival in the absence of SOD.

Manganese: its acquisition by and function in the lactic acid bacteria

The transition metal manganese is considered to be a minor micronutrient in both pro- and eukaryotes, usually being required from the environment at subnanomolar levels. Until recently, Mn was only known to function in cells as a cofactor for a few enzymatic reactions. A notable exception has been reported in many lactic acid bacterial species which require micromolar medium Mn levels for growth and contain up to 35 mM Mn. These high Mn concentrations are accompanied by the near or complete absence of intracellular iron and superoxide dismutase (SOD). Lacking hemes, Lactobacillus plantarum and related species contain a unique Mn-cofactored catalase as well as millimolar Mn(II) in a nonenzymic complex performing the function of the micromolar superoxide dismutase found in most other aerotolerant cells. The high Mn(II) levels are accumulated via an efficient active transport system and are stored intracellularly in a high molecular weight complex. Study of Lactobacillus plantarum has provided an interesting example of the substitution of Mn for Fe in several of the biological roles of Fe, an alternative mechanism of aerotolerance, and a better understanding of the unique biochemistry of the lactic acid bacteria.

Influence of Manganese on Growth of a Sheathless Strain of Leptothrix discophora

Mn 2+ exerted various effects on the growth of Leptothrix discophora strain SS-1 in batch cultures depending on the concentration added to the medium. Concentrations of 0.55 to 5.5 μM Mn 2+ , comparable to those in the environment from which strain SS-1 was isolated, decreased cell yield and prolonged stationary-phase survival, but did not affect growth rate. Elevated concentrations of 55 to 910 μM Mn 2+ also decreased cell yield and prolonged survival, but growth rate was decreased as well. The addition of 1,820 μM Mn 2+ caused a decline in cell numbers followed by an exponential rise after 80 h of incubation, indicating the development of a population of cells resistant to Mn 2+ toxicity. When 360 μM Mn 2+ or less was added to growth flasks, Mn 2+ was oxidized to manganese oxide (MnO x , where x is ∼2), which appeared as brown particles in the medium. Quantification of Mn oxidation during growth of cultures to which 55 μM Mn 2+ was added showed that nearly all of the Mn 2+ was oxidized by the beginning of the stationary phase of growth (15 to 25 h). This result suggested that the decrease in cell yield observed at low and moderate concentrations of Mn 2+ was related to the formation of MnO x , which may have bound cationic nutrients essential to the growth of SS-1. The addition of excess Fe 3+ to cultures containing 55 μM Mn 2+ increased cell yield to levels near those found in cultures with no added Mn 2+ , indicating that iron deprivation by MnO x was at least partly responsible for the decreased cell yield.

Purification and biochemical characterization of pyruvate oxidase from Lactobacillus plantarum

Pyruvate oxidase (EC 1.2.3.3) was isolated and characterized from Lactobacillus plantarum. The enzyme catalyzes the oxidative decarboxylation of pyruvate in the presence of phosphate and oxygen, yielding acetyl phosphate, carbon dioxide, and hydrogen peroxide. This pyruvate oxidase is a flavoprotein, with the relatively tightly bound cofactors flavin adenine dinucleotide, thiamine pyrophosphate, and a divalent metal ion, with Mn2+ being the most effective. The enzyme is only slightly inhibited by EDTA, implying that the enzyme-bound metal ion is poorly accessible to EDTA. Only under relatively drastic conditions, such as acid ammonium sulfate precipitation, could a colorless and entirely inactive apoenzyme be obtained. A partial reactivation of the enzyme was only possible by the combined addition of flavin adenine dinucleotide, thiamine pyrophosphate, and MnSO4. The enzyme has a molecular weight of ca. 260,000 and consists of four subunits with apparently identical molecular weights of 68,000. For catalytic activity the optimum pH is 5.7, and the optimum temperature is 30 degrees C. The Km values for pyruvate, phosphate, and arsenate are 0.4, 2.3, and 1.2 mM, respectively. The substrate specificity revealed that the enzyme reacts also with certain aldehydes and that phosphate can be replaced by arsenate. In addition to oxygen, several artificial compounds can function as electron acceptors.

Correlation of oxygen utilization and hydrogen peroxide accumulation with oxygen induced enzymes in Lactobacillus plantarum cultures

Two strains of Lactobacillus plantarum accumulated H2O2 when grown aerobically in a complex glucose based medium. The H2O2 accumulation did not occur immediately on exposure of the culture to O2 but was delayed for a time which, in the case of one strain, was dependent on the amount of inoculum used to seed the culture. The accumulation was always preceded by an increase in the rate of O2 utilization by the cultures. The latter coincided approximately with an increase in specific activity of NADH oxidase, pyruvate oxidase and NADH peroxidase. H2O2 was not a product of NADH oxidase in vitro but was formed in substantial quantities from O2 during oxidation of pyruvate. The three enzymes were induced by O2 and H2O2; the induction of NADH oxidase responded to lower levels of O2 (but not of H2O2) than the pyruvate oxidase or the NADH peroxidase.

Manganese acquisition by Lactobacillus plantarum

Lactobacillus plantarum has an unusually high Mn(II) requirement for growth and accumulated over 30 mM intracellular Mn(II). The acquisition of Mn(II) by L. plantarum occurred via a specific active transport system powered by the transmembrane proton gradient. The Mn(II) uptake system has a Km of 0.2 microM and a Vmax of 24 nmol mg-1 of protein min-1. Above a medium Mn(II) concentration of 200 microM, the intracellular Mn(II) level was independent of the medium Mn(II) and unresponsive to oxygen stresses but was reduced by phosphate limitation. At a pH of 5.5, citrate, isocitrate, and cis-aconitate effectively promoted MN(II) uptake, although measurable levels of 1,5-[14C]citrate were not accumulated. When cells were presented with equimolar Mn(II) and Cd(II), Cd(II) was preferentially taken up by the Mn(II) transport system. Both Mn(II) and Cd(II) uptake were greatly increased by Mn(II) starvation. Mn(II) uptake by Mn(II)-starved cells was subject to a negative feedback regulatory mechanism functioning less than 1 min after exposure of the cells to Mn(II) and independent of protein synthesis. When presented with a relatively large amount of exogenous Mn(II), Mn(II)-starved cells exhibited a measurable efflux of their internal Mn(II), but the rate was only a small fraction of the maximal Mn(II) uptake rate.

31P-NMR and ESR studies of the oxidation states of manganese in Staphylococcus aureus

High-resolution 31P-NMR and ESR spectroscopies are used to probe the role of manganese in oxygen metabolism, in vivo, by Staphylococcus aureus. The linewidth of the intracellular orthophosphate resonance in the 31P-NMR spectrum and the amplitude of the ESR sextet of signals due to Mn2+ hexaquo ions are found to be sensitive to the oxygenation state of the cells. These results are attributed to changes in the oxidation state of the manganese. It is concluded that manganous ions are oxidized to Mn3+ in oxygenated cells. Mn3+ is in turn reduced to Mn2+ under anaerobic conditions. The Mn2+ is also oxidized to Mn3+ by hydrogen peroxide probably as a result of the disproportionation of H2O2 to H2O and O2 by an active catalase in S. aureus. Addition of mercaptoethanol to a suspension of oxygenated cells results in the reduction of Mn3+ to Mn2+.

The toxicology of molecular oxygen

Molecular oxygen, itself not very reactive, can be converted by photosensitization to electronically excited singlet states, and by partial reduction to the superoxide and hydroxyl free radicals and to hydrogen peroxide. The very considerable toxicity of oxygen, which is due primarily to the properties of these derivatives, is ordinarily overlooked because aerobes have evolved an elaborate system of defenses which is reasonably adequate under ambient conditions. This toxicity becomes all too apparent when these defenses are overwhelmed at elevated pO2 or through the action of compounds which increase the conversion of oxygen to its more reactive derivatives. We will here consider the threat posed by oxygen and the defenses which make aerobic life possible.

Carbohydrate metabolism in lactic acid bacteria

The term "lactic acid bacteria" is discussed. An overview of the following topics is given: main pathways of homo- and heterofermentation of hexoses, i.e. glycolysis, bifidus pathway, 6-phosphogluconate pathway; uptake and dissimilation of lactose (tagatose pathway); fermentation of pentoses and pentitols; alternative fates of pyruvate, i.e. splitting to formate and acetate, CO2 and acetate or formation of acetoin and diacetyl; lactate oxidation; biochemical basis for the formation of different stereoisomers of lactate.

Functional significance of manganese catalase in Lactobacillus plantarum

A strain of Lactobacillus plantarum which was unable to produce manganese (Mn)catalase (ATCC 8014) grew somewhat more rapidly and to a slightly higher plateau density than did an Mn catalase-positive strain (ATCC 14421), and this was the case during aerobic or anaerobic growth. However, when maintenance of viability was measured during the stationary phase of the growth cycle, the advantage provided by Mn catalase was obvious. Thus, the viability of ATCC 14431 was undiminished over 21 h of aerobic incubation, during the stationary phase, whereas that of ATCC 8014 decreased by seven orders of magnitude. Addition of catalase to the medium or growth in the presence of hemin, which allows catalase synthesis, protected ATCC 8014 against this loss of viability. Suppression of Mn catalase within ATCC 14431 by treatment with NH2OH caused the cells to lose viability when exposed to 4 mM H2O2.

Oxygen dependence of sister-chromatid exchanges

We have studied the dependent of sister-chromatid exchange (SCE) production on the presence of oxygen during incubation of cells in 5-bromodeoxyuridine (BrdUrd) by analyzing the SCE yields in second-division chromosomes of Allium cepa L. meristem cells. We considered the cases between 10 and 100% oxygen in the incubation medium. Under these experimental situations no significant modifications in cell-cycle duration were obtained. Our results lead us to conclude that: (1) in oxygenated treatments, cells incubated during 2 consecutive cycles in the presence of BrdUrd show significantly higher SEC frequencies (in second-division chromosomes) than those treated only during the first cycle; (2) SCE frequencies increase as a function oxygen tension; and (3) oxygen-dependent SCE frequencies increase as a function of oxygen tension and (3) oxygen-dependent SCes appear to be found by exchanging post-replicative DNA portions. These observations suggest that the experimental protocol reported here could be useful in determining both the precise moment of action of an agent during the cell cycle and the DNA portions actively involved in physically and chemically provoked SCEs.

Iron in neoplastic disease

Normal and neoplastic cells have similar needs for iron, but the latter may exhibit altered mechanisms of iron acquisition that permit continued multiplication in host iron-restricted tissues. For example, neoplastic cells may form low molecular weight siderophores as well as increase the number of transferrin binding glycoproteins on their cell surfaces. The hosts attempt to withhold iron from neoplastic cells by preventing the return of the metal to plasma and diverting it to storage, by increasing the synthesis of ferritin to accommodate the added stores, and by surrounding tumor cells with macrophages that can ingest lactoferrin-bound iron, but these mechanisms are often not effective against the iron-accumulating mechanisms of the tumor. Persons or animals with iron overload (via ingestion, inhalation, injection, or pathophysiologic process) tend to be at greater risk than normal hosts in the development of neoplasms. The tumors are often associated with the site(s) of deposition of the metal. In addition to its neoplastic cell nutrient function, excess iron might suppress tumorcidal action of macrophages and interfere with lymphocyte traffic. Severe iron deficiency can interfere with the ability of the host to detoxify potential carcinogens as well as with its ability to activate antitumor lymphocytes.

Distribution of superoxide dismutase, catalase, and peroxidase activities among Treponema pallidum and other spirochetes

Representative members of Spirochaetales were surveyed for their content of superoxide dismutase (SOD), catalase, and peroxidase activities. Only Leptospira exhibited peroxidase activity. Obligately anaerobic cultivable Treponema and Spirochaeta possessed no SOD or peroxidative capabilities. Upon polyacrylamide gel electrophoresis, Spirochaeta aurantia, Borrelia hermsi, and five Leptospira biflexa serovars showed SOD activity associated with one electrophoretic band which was inhibited by H2O2, suggesting that they were iron-containing dismutases. These spirochetes could be distinguished by differences in relative mobilities of their SODs. SOD activity, but not catalase activity, was induced aerobically in S. aurantia. All Leptospira interrogans serovars and two L. biflexa serovars lacked significant SOD activity. These SOD-deficient strains of Leptospira, with one exception, possessed high levels of catalase activity. The Nichols strain of virulent Treponema pallidum possessed SOD and catalase activities, but lacked peroxidase activity. The SOD in T. pallidum exhibited two electrophoretic bands containing copper and zinc, and its relative mobility was identical to that of purified rabbit SOD. Immunization of sheep with purified rabbit SOD resulted in antiserum which inhibited both rabbit SOD and T. pallidum SOD assayed by spectrophotometric analysis or activity staining following polyacrylamide gel electrophoresis. In agarose gel diffusion, precipitin lines of identity were observed between purified rabbit SOD and cell extracts of T. pallidum. These data indicated that the SOD activity detected in T. pallidum was host derived.

Manganese, superoxide dismutase, and oxygen tolerance in some lactic acid bacteria

A previous study of the aerotolerant bacterium Lactobacillus plantarum, which lacks superoxide dismutase (SOD), demonstrated that it possesses a novel substitute for this defensive enzyme. Thus, L. plantarum contains 20 to 25 mM Mn(II),m in a dialyzable form, which is able to scavenge O2- apparently as effectively as do the micromolar levels of SOD present in most other organisms. This report describes a survey of the lactic acid bacteria. The substitution of millimolar levels of Mn(II) for micromolar levels of SOD is a common occurrence in this group of microorganisms, which contained either SOD or high levels of Mn(II), but not both. Two strains were found which had neither high levels of Mn(II) nor SOD, and they were, as was expected, very oxygen intolerant. Lactic acid bacteria containing SOD grew better aerobically than anaerobically, whereas the organisms containing Mn(II) in place of SOD showed aerobic growth which was best, at best, equal to anaerobic growth. Plumbagin (5-hydroxy-2-methyl-1,4-naphthoquinone) increases the rate of O2- production in these organisms. Lactobacillus strains containing high intracellular Mn(II) were more resistant to the oxygen-dependent toxicity of plumbagin than were strains containing lower levels of Mn(II). The results support the conclusion that a high internal level of Mn(II) provides these organisms with an important defence against endogenous O2-.