Sodium nitroprusside may modulate Escherichia coli antioxidant enzyme expression by interacting with the ferric uptake regulator

Efforts to explore possible relationships between nitric oxide (NO) and antioxidant enzymes in an Escherichia coli model have uncovered a possible interaction between sodium nitroprusside (SNP), a potent, NO-donating drug, and the ferric uptake regulator (Fur), an iron(II)--dependent regulator of antioxidant and iron acquisition proteins present in Gram-negative bacteria. The enzymatic profiles of superoxide dismutase and hydroperoxidase during logarithmic phase of growth were studied via non-denaturing polyacrylamide gel electrophoresis and activity staining specific to each enzyme. Though NO is known to induce transcription of the manganese-bearing isozyme of SOD (MnSOD), treatment with SNP paradoxically suppressed MnSOD expression and greatly enhanced the activity of the iron-containing equivalent (FeSOD). Fur, one of six global regulators of MnSOD transcription, is uniquely capable of suppressing MnSOD while enhancing FeSOD expression through distinct mechanisms. We thus hypothesize that Fur is complacent in causing this behaviour and that the iron(II) component of SNP is activating Fur. E. coli was also treated with the SNP structural analogues, potassium ferricyanide (PFi) and potassium ferrocyanide (PFo). Remarkably, the ferrous PFo was capable of mimicking the SNP-related pattern, whereas the ferric PFi was not. As Fur depends upon ferrous iron for activation, we submit this observation of redox-specificity as preliminary supporting evidence for the hypothesized Fur-SNP interaction. Iron is an essential metal that the human innate immune system sequesters to prevent its use by invading pathogens. As NO is known to inhibit iron-bound Fur, and as activated Fur regulates iron uptake through feedback inhibition, we speculate that the administration of this drug may disrupt this strategic management of iron in favour of residing Gram-negative species by providing a source of iron in an otherwise iron-scarce environment capable of encouraging its own uptake. However, these gains may be counteracted by the oxidative consequences of iron and NO, as the former can catalyse the formation of toxic free radical species while the latter can inhibit enzymes and contribute to the formation of other toxic compounds. The potential consequences of SNP on microbial growth warrant future investigation.

The fatty acid profile of vegetative Azotobacter vinelandii ATCC 12837: growth phase-dependence

Fatty acids of Azotobacter vinelandii ATCC 12837 were determined at various times during aerobic vegetative growth at 30 degrees C to provide baseline data for studying the effects of chemical agents on the organism's survival and fatty acid biosynthesis. Palmitate (16:0) was the highest at 36.7+/-4.3 mol% (mean+/-SD) after the first 5 h in fresh culture, decreasing slightly to 33.4+/-2.6 mol% at 49 h. The other fatty acids were therefore each normalized as a ratio of 16:0. At 5 h, as a ratio of 16:0, myristate (14:0) was 0.14+/-0.06, palmitoleate (16:1cDelta9-10) 0.13+/-0.06, oleate (18:1cDelta9-10) 0.21+/-0.12, cis-vaccenate (18:1cDelta11-12) 0.30+/-0.17 and stearate (18:0) 0.68+/-0.02. As the growth phase advanced to 49 h, 14:0 and 16:1cDelta9-10 increased, 18:1cDelta9-10 decreased and cis-vaccenate reciprocally increased, whereas 18:0 decreased. These suggest that the saturated fatty acid biosynthesis pathway yielded 16:0 and 18:0 in the 5-h lag period. By desaturation, 18:0 formed the unsaturated fatty acid (UFA) 18:1cDelta9-10. As the culture aged, the anaerobic UFA biosynthesis pathway formed 16:1cDelta9-10, which was elongated to 18:1cDelta11-12. These fatty acid alterations represent a homeoviscous adaptation, modulating the microbe's membrane lipid viscosity for optimal cellular function.

Effects of opsonization and gamma interferon on growth of Brucella melitensis 16M in mouse peritoneal macrophages in vitro

Entry of opsonized pathogens into phagocytes may benefit or, paradoxically, harm the host. Opsonization may trigger antimicrobial mechanisms such as reactive oxygen or nitric oxide (NO) production but may also provide a safe haven for intracellular replication. Brucellae are natural intramacrophage pathogens of rodents, ruminants, dogs, marine mammals, and humans. We evaluated the role of opsonins in Brucella-macrophage interactions by challenging cultured murine peritoneal macrophages with Brucella melitensis 16M treated with complement- and/or antibody-rich serum. Mouse serum rich in antibody against Brucella lipopolysaccharide (LPS) (aLPS) and human complement-rich serum (HCS) each enhanced the macrophage uptake of brucellae. Combinations of suboptimal levels of aLPS (0. 01%) and HCS (2%) synergistically enhanced uptake. The intracellular fate of ingested bacteria was evaluated with an optimal concentration of gentamicin (2 microg/ml) to control extracellular growth but not kill intracellular bacteria. Bacteria opsonized with aLPS and/or HCS grew equally well inside macrophages in the absence of gamma interferon (IFN-gamma). Macrophage activation with IFN-gamma inhibited replication of both opsonized and nonopsonized brucellae but was less effective in inhibiting replication of nonopsonized bacteria. IFN-gamma treatment of macrophages with opsonized or nonopsonized bacteria enhanced NO production, which was blocked by N(G)-monomethyl L-arginine (MMLA), an NO synthesis inhibitor. MMLA also partially blocked IFN-gamma-mediated bacterial growth inhibition. These studies suggest that primary murine macrophages have limited ability to control infection with B. melitensis, even when activated by IFN-gamma in the presence of highly opsonic concentrations of antibody and complement. Additional cellular immune responses, e.g., those mediated by cytotoxic T cells, may play more important roles in the control of murine brucellosis.

Membrane fluidity, reactive oxygen species, and cell-mediated immunity: implications in nutrition and disease

Membrane-associated functions are profoundly influenced by the fluidity and physical state of the membrane. These two features are in turn determined by the membrane lipid acyl chain profile. Reactive oxygen species (ROS) modify the acyl chains by lipid peroxidation of the unsaturated chains, thus affecting the fluidity and physical state of the membrane. By enhancing endogenous ROS levels, therefore, aging, and disease affect integral membrane function, such as the cell-mediated immune (CMI) reaction involving phagocyte membrane NADPH oxidase. This enzyme relies on triggering by membrane-inserted protein kinase C (PKC), for its superoxide (O2-) producing function. The molecular mechanism of the depressed immunocompetence in the aged, and in disease and malnutrition, may reside in the down-regulation of these two enzymes by excess ROS. These excess ROS arise from activated phagocytes in disease states, and from enhanced ROS from other sources in the aged, as well as from the decrease in antioxidants in the aged. Research should be intensified on PKC and NADPH oxidase function with the aim of unravelling the molecular mechanism of the depressed immunocompetence, and thence, of formulating appropriate intervention strategies against it.

Towards more efficacious chemotherapy of trypanosomiasis: combination of alpha-difluoromethylornithine (DFMO) with reactive oxygen generating drugs

Trypanosomiasis (whether African sleeping sickness, or American Chaga's disease) is caused by an infection with a protozoan parasite, i.e. the trypanosome. This carries fatal sequences in the untreated host. Currently available chemotherapeutic drugs (some of which cure by involving reactive oxygen species (ROS] are not optimally adequate. They are toxic as well, and may also be carcinogenic. It is therefore desirable to devise better chemotherapeutic regimens. ROS destroy the parasite, but excess ROS damage host tissue and are potentially carcinogenic. Alpha-difluoromethylornithine (DFMO) inhibits ornithine decarboxylase and so lowers the levels of spermine and spermidine. This singular effect in the parasite inhibits its multiplication, whereas in the host tissue it prevents carcinogenesis by preventing cell proliferation. Thus, combination of ROS-generating drugs with DFMO would be very effective against trypanosomiasis, and would be without cancer risk too. The combination is therefore advocated for chemotherapy of trypanosoma infections. This necessities experimental investigations specifically directed towards establishing the optimally efficacious combination of DFMO with the drugs.

Avoidance, and inactivation of reactive oxygen species: novel microbial immune evasion strategies

A prominent aspect of host cell-mediated immune (CMI) reactions leading to the clearance of infections is the production of one or more reactive oxygen species (ROS) such as superoxide (O2-), hydrogen peroxide (H2O2), hydroxyl radical (OH.), and hypohalite (e.g., OC1-). These ROS are usually produced by phagocytes. A number of chemotherapeutic agents also produce ROS in the process of their curative mechanisms. In a variety of infections, these ROS constitute a formidable arsenal in the clearance of the infection. In some cases, the excess ROS could also cause tissue damage. Evidence is herewith presented that pathogenic intracellular microorganisms, in order to enhance their survival as well as effective virulence within the host, have evolved novel strategies in the nature of avoidance, or inhibition of ROS production by phagocytes, or neutralization of already produced ROS. It is advocated that more in depth studies be undertaken in these respects in order to be able to exploit these phenomena in the production of more efficacious chemotherapeutic agents and anti-pathogen vaccines.

Reactive oxygen production against malaria--a potential cancer risk factor

In response to malaria infection, phagocytes, such as macro-phages and neutrophils, produce superoxide and thence the other reactive oxygen species (ROS) with which to kill the parasites. Excess ROS is normally eliminated by the body's natural scavenger molecules; however, in the event of a vast excess of ROS, as may be the case in acute as well as chronic malaria patients, the natural scavengers may be overwhelmed. We hypothesize that unscavenged ROS in malaria patients causes DNA damage in normal host cells which, if unrepaired or incorrectly repaired, could result in oncogene activation and eventually lead to cancer. An epidemiologic study may be warranted in malaria-endemic regions to investigate the possible relationship between malaria infection and cancer risk.

Requirement for lipopolysaccharide for enhanced in vitro superoxide producing competence in macrophages from normal and malaria (Plasmodium chabaudi) infected mouse spleen

Nucleated cells from mouse spleens were suspended in RPMI-1640 medium and plated in polystyrene tissue culture dishes with or without lipoplysaccharide (LPS, endotoxin) and incubated at 37 degrees C for 3 h in a humid incubator under 5% CO2. Adherent spleen cells obtained from uninfected control or Plasmodium chabaudi-infected mice showed negligible superoxide (O2) production in vitro, in response to triggering with phorbol myristate acetate (PMA). However, O2 release increased in a concentration-dependent fashion as LPS was introduced above a threshold of about 10 ng/ml. This LPS dependence is at least 100 times more than that required by mouse peritoneal macrophages and 10(6) times greater than the requirement reported for human monocytes. These findings emphasize the differences among the three mononuclear cells, and also suggest that LPS could prove useful in the isolation and culture of other metabolically competent cells.

Lipid and temperature dependence of the kinetic and thermodynamic parameters for active amino acid transport in Escherichia coli K1060

The influence of membrane physical state on the kinetic and thermodynamic parameters for the active transport systems for two amino acids has been investigated in Escherichia coli K1060, an unsaturated fatty acid auxotrophic mutant. The apparent Michaelis constant (Km) for the uptake of L-[14C]glutamine (0.05 to 0.08 microM) or L-[14C]proline (1 microM approx.) is invariant with temperature for this mutant grown on elaidate (18:1t), palmitelaidate (16:1t), oleate (18:1c), palmitoleate (16:1c) and linoleate (18:2c,c). Arrhenius plots of the maximum velocities (Vmax) for L-glutamine transport in cells grown on 16:1t, 18:1c and 16:1c are biphasic within a limited temperature range peculiar to each UFA supplementation. Above an upper temperature limit also displayed by 18:1t and 18:2c,c-cells, Vmax decreases with temperature. A characteristic temperature (Tb) marks the point of intersection of the biphasic slope of the Arrhenius plots, and activation energy (Ea) is lower above than below Tb. Differential thermal analysis considered with membrane lipid fatty acyl profiles indicates that the upper temperature limit is governed by both membrane lipid acyl chain fluidity and heterogeneity, while Tb is governed by fluidity alone. Data on L-proline transport Vmax are similar, but the upper temperature limit and Tb are each shifted to lower temperatures relative to L-glutamine. We suggest that membrane defects related to energy-coupling and caused by abnormal fluidity and physical state are responsible for the peculiar temperature dependences of Vmax for these active transport processes.

Effects of oxygen free radical scavengers on the membrane myoinositol dehydrogenase of Bacillus pumilus strain 5

Micromolar amounts of superoxide dismutase (SOD) or parabenzoquinone (PBQ) inhibit the membrane-bound myoinositol dehydrogenase of Bacillus pumilus strain 5 in the mode of this enzyme transferring electrons to 2,6-dichlorophenol indophenol (DCPIP). The inhibition trends are similar to those reported earlier by us for the inhibition by mannitol and benzoate. We postulate that the transfer of electrons from the enzyme to DCPIP involves in its rate-limiting step, a catalytic intermediate in the nature of superoxide (O2-) and/or hydroyl free radical (OH.). Scavenging of any one or both of these radicals, therefore, inhibits the electron transfer reaction. PBQ serves as an electron sink in the reaction preventing the reduction of DCPIP.

The effect of alterations in the fluidity and phase state of the membrane lipids on the passive permeation and facilitated diffusion of glycerol in Escherichia coli

The passive permeation and facilitated diffusion of glycerol into Escherichia coli K 1060, an unsaturated fatty acid auxotroph, were studied as a function of temperature and membrane lipid fatty acid composition using a stopped-flow spectrophotometric assay of glycerol permeation. The relative rates of glycerol passive and mediated entry were both significantly influenced by the fluidity of the membrane lipids, increasing as the gel to liquid-crystalline phase transition midpoint temperature of the membrane lipids decreased. The rate of passive glycerol permeation, but not the rate of glycerol facilitated diffusion, decreased as the membrane lipids were converted to the gel state. The apparent activation energies for passive and facilitated diffusion of glycerol, measured in cells whose membrane lipids were in the liquid-crystalline state, were 15-16 and 10-11 kcal mol-1, respectively, and neither value was significantly influenced by the fatty acid composition or fluidity of the membrane lipids. The mechanistic implications of these observations for the function of the glycerol facilitated diffusion system of E. coli are discussed.

Stopped-flow spectrophotometric assay of glycerol permeation in Escherichia coli: applicability and limitations

The passive permeation and facilitated diffusion of glycerol in various strains of Escherichia coli have been studied by stopped-flow spectrophotometry. Contrary to the prediction for glycerol entry by simple diffusion, the reciprocal relaxation time (1/tau, s-1) for the passive permeation of glycerol in cells grown in the presence of glucose was not constant but decreased as the glycerol concentration increased above 100 mM. This anomaly was not due to refractive index differences or to the presence of residual levels of the glycerol facilitator protein in non-induced cells. Although reciprocal relaxation times for glycerol-induced E. coli exhibited the expected elevation relative to non-induced cells, a similar anomalous decrease 1/tar (s-1) with increasing glycerol concentration was observed. In addition, at early times after suspension in dilute buffer, the 1/tau (s-1) values obtained for induced or non-induced E. coli swelling in glycerol were considerably greater than for organisms incubated in dilute buffer for longer times. We concluded that either this spectrophotometric technique was not monitoring solely the permeation of glycerol into E. coli, or concentrations of glycerol above 100 mM significantly perturbed the structure of the E. coli cell envelope.