Specific Inhibition of Nitrite Oxidation by Chlorate and Its Use in Assessing Nitrification in Soils and Sediments

A method was developed to determine the ammonium oxidation rate (potential) of unenriched natural samples by measuring the nitrite produced in shaken slurries. Addition of chlorate to the samples prevented nitrite from being oxidized to nitrate. The effectiveness and specificity of chlorate were tested with pure cultures of nitrite and ammonium oxidizers, as well as in soil and sediment slurries. It was concluded that chlorate had relatively little inhibitory effect on ammonium oxidation. However, under some conditions chlorate was not completely effective in blocking nitrite oxidation, and the causes of this were investigated. The technique was designed to check for incomplete blockage.     

Differential Inhibition by Allylsulfide of Nitrification and Methane Oxidation in Freshwater Sediment

Addition of nitrapyrin, allylthiourea, C(inf2)H(inf2), and CH(inf3)F to freshwater sediment slurries inhibited CH(inf4) oxidation and nitrification to similar extents. Dicyandiamide and allylsulfide were less inhibitory for CH(inf4) oxidation than for nitrification. Allylsulfide was the most potent inhibitor of nitrification, and the estimated 50% inhibitory concentrations for this process and CH(inf4) oxidation were 0.2 and 121 (mu)M, respectively. At a concentration of 2 (mu)M allylsulfide, growth and CH(inf4) oxidation activity of Methylosinus trichosporium OB3b were not inhibited. Allylsulfide at 200 (mu)M inhibited the growth of M. trichosporium by approximately 50% but did not inhibit CH(inf4) oxidation activity. Nitrite production by cells of M. trichosporium was not significantly affected by allylsulfide, except at a concentration of 2 mM, when growth and CH(inf4) oxidation were also inhibited by about 50%. Methane monooxygenase activity present in soluble fractions of M. trichosporium was not inhibited significantly by allylsulfide at either 200 (mu)M or 2 mM. These results suggest that the partial inhibition of CH(inf4) oxidation in sediment slurries by high allylsulfide concentrations may be caused by an inhibition of the growth of methanotrophs rather than an inhibition of methane monooxygenase activity specifically. We conclude that allylsulfide is a promising tool for the study of interactions of methanotrophs and nitrifiers in N cycling and CH(inf4) turnover in natural systems.     

乙炔抑制法在硝化与反硝化过程中的应用

硝化和反硝化作用在土壤氮素循环中扮演重要作用,由于硝化和反硝化作用一方面能够导致土壤中氮素的损失,另一方面能够产生温室气体-N2O,所以硝化和反硝化作用的研究备受关注.乙炔抑制法能同时测定硝化和反硝化作用,在硝化和反硝化作用中有着重要的应用.该文主要论述了乙炔抑制法的研究进展;以及对应用乙炔气体时存在的一些问题进行了综述.     

Growth Inhibition of Staphylococci by Sodium Thiosulphate

The addition of sodium thiosulphate to a medium as neutralizer of an iodine antiseptic resulted in unexpected growth inhibition of various strains of staphylococci and micrococci. The minimum growth inhibiting concentration varied with different strains. The inhibitory effect of sodium thiosulphate was more pronounced in media with low pH values than in those with high pH values, and was diminished by the addition of Tween 80. The action was also found to depend on the concentration of l -cystine in the medium. It is suggested that the use of sodium thiosulphate be avoided in growth media designed to neutralize iodine in disinfection efficiency tests when staphylococci or micrococci are used as test organisms.     

Bacteria and Acidic Drainage from Coal Refuse: Inhibition by Sodium Lauryl Sulfate and Sodium Benzoate

The application of an aqueous solution of sodium lauryl sulfate and sodium benzoate to the surface of high-sulfur coal refuse resulted in the inhibition of iron-and sulfur-oxidizing chemoautotrophic bacteria and in the decrease of acidic drainage from the refuse, suggesting that acid drainage can be abated in the field by inhibiting iron- and sulfur-oxidizing bacteria.     

Sodium Transport from Blood to Brain: Inhibition by Furosemide and Amiloride

Abstract: Brain sodium uptake in vivo was studied using a modified intracarotid bolus injection technique in which the uptake of ²²Na ⁺ was compared with that of the relatively impermeable molecule, [³H]l-glucose. At a Na ⁺ concentration of 1.4 m M , Na ⁺ uptake was 1.74 ± 0.07 times greater than l -glucose uptake. This decreased to 1.34 ± 0.04 at 140 m M Na ⁺, indicating saturable Na ⁺ uptake. Relative Na ⁺ extraction was not affected by pH but was inhibited by amiloride ( K _i= 3 ± 10⁻⁷ M ) and by 1 m M furosemide. The effects of these two inhibitors were additive. Brain uptake of ⁸⁶Rb ⁺, a K ⁺ analogue, was measured to study interaction of K ⁺ with Na ⁺ transport systems. Relative ⁸⁶Rb ⁺ extraction was also inhibited by amiloride; however, it was not inhibited by furosemide. The results suggest the presence of two distinct transport systems that allow Na ⁺ to cross the luminal membrane of the brain capillary endothelial cell. These transport systems could play an important role in the movement of Na ⁺ from blood to brain.     

Chlorate: a reversible inhibitor of proteoglycan sulfation

Bovine aorta endothelial cells were cultured in medium containing [3H]glucosamine, [35S]sulfate, and various concentrations of chlorate. Cell growth was not affected by 10 mM chlorate, while 30 mM chlorate had a slight inhibitory effect. Chlorate concentrations greater than 10 mM resulted in significant undersulfation of chondroitin. With 30 mM chlorate, sulfation of chondroitin was reduced to 10% and heparan to 35% of controls, but [3H]glucosamine incorporation on a per cell basis did not appear to be inhibited. Removal of chlorate from the culture medium of cells resulted in the rapid resumption of sulfation.     

Inhibition of the Indole Test Reaction by Sodium Nitrite

Sodium nitrite formed by nitrate reduction produced a false-negative reaction in the detection of indole formation when both tests were conducted in one medium.     

The Inhibition of Foam Cell Formation by Sodium Diethyldithiocarbamate

A prominent feature of human atherosclerosis is the lipid-laden foamy macrophage, which often also contains the insoluble pigment, ceroid. The culture of macrophage-like cells, P388Dis, with artificial lipoproteins composed of cholesteryl linoleate (CL) and bovine serum albumin (BSA) results in foam cell formation with lipoprotein uptake and the intracellular accumulation of ceroid. Ceroid accumulation is accompanied by the oxidation of the cholesterol ester as monitored by gas chromatography. The sodium salt of diethyldithio-carbamic acid (DDC) at 1-5 μM effectively inhibited lipoprotein uptake, cholesteryl linoleate oxidation and ceroid accumulation in cultures of P388D₁. Further studies showed that intracellular ceroid accumulation appeared to require the presence of cystine in the medium. Lipoprotein oxidation by this macrophage-like cell therefore appears to involve a mechanism dependent on cystine metabolism which is consistent with previous reports of macrophage-mediated lipoprotein oxidation. Studies on CL/BSA-induced ceroid accumulation in human monocytes also showed that DDC behaved in much the same manner. This inhibitory effect of DDC on foam cell formation, often considered a primary event of atherosclerosis, at concentrations as low as 1 μM, suggests the need for further, more comprehensive, studies on this compound's activities.     

Differential Chlorate Inhibition of Chaetomium globosum Germination, Hyphal Growth, and Perithecia Synthesis

Chaetomium globosum Kunze:Fr is a dermatophytic, dematiaceous fungus that is ubiquitous in soils, grows readily on cellulolytic materials, and is commonly found on water-damaged building materials. Chlorate affects nitrogen metabolism in fungi and is used to study compatibility among anamorphic fungi by inducing nit mutants. The effect of chlorate toxicity on C. globosum was investigated by amending a modified malt extract agar (MEA), oat agar, and carboxymethyl cellulose agar (CMC) with various levels of potassium chlorate (KClO₃). C. globosum perithecia production was almost completely inhibited (90–100?%) at low levels of KClO₃ (0.1?mM) in amended MEA. Inhibition of perithecia production was also observed on oat agar and CMC at 1?and 10?mM, respectively. However, hyphal growth in MEA was only inhibited 20?% by 0.1–100?mM KClO₃ concentrations. Hyphal growth was never completely inhibited at the highest levels tested (200?mM). Higher levels of KClO₃ were needed on gypsum board to inhibit perithecia synthesis. In additional experiments, KClO₃ did not inhibit C. globosum, Fusarium oxysporum, Aspergillus niger, Penicillum expansum, and airborne fungal spore germination. The various fungal spores were not inhibited by KClO₃ at 1–100?mM levels. These results suggest that C. globosum perithecia synthesis is more sensitive to chlorate toxicity than are hyphal growth and spore germination. This research provides basic information that furthers our understanding about perithecia formation and may help in developing control methods for fungal growth on building materials.     

Inhibition of Spores of Clostridium spp. by Sodium Nitrite

S ummary . Sodium nitrite heated in a laboratory medium was more inhibitory to spores of Clostridium spp. than nitrite added as a filter-sterilized solution to the same medium. Most spores remained refractile after inhibition for >3 months and some proved viable when inoculated into fresh nitrite-free medium. The inhibitory activity of heated nitrite medium was not stable indefinitely, growth sometimes occurred on re-inoculation with vegetative cells.     

Inhibition of Nitrification Alters Carbon Turnover in the Patagonian Steppe

Human activities are altering biodiversity and the nitrogen (N) cycle, affecting terrestrial carbon (C) cycling globally. Only a few specialized bacteria carry out nitrification—the transformation of ammonium (NH ₄ ⁺ ) to nitrate (NO ₃ ⁻ ), in terrestrial ecosystems, which determines the form and mobility of inorganic N in soils. However, the control of nitrification on C cycling in natural ecosystems is poorly understood. In an ecosystem experiment in the Patagonian steppe, we inhibited autotrophic nitrification and measured its effects on C and N cycling. Decreased net nitrification increased total mineral N and NH ₄ ⁺ and reduced NO ₃ ⁻ in the soil. Plant cover (P < 0.05) and decomposition (P < 0.0001) decreased with inhibition of nitrification, in spite of increases in NH ₄ ⁺ availability. There were significant changes in the natural abundance of δ¹⁵N in the dominant vegetation when nitrification was inhibited suggesting that a switch occurred in the form of N (from NO ₃ ⁻ to NH ₄ ⁺ ) taken up by plants. Results from a controlled-condition experiment supported the field results by showing that the dominant plant species of the Patagonian steppe have a marked preference for nitrate. Our results indicate that nitrifying bacteria exert a major control on ecosystem functioning, and that the inhibition of nitrification results in significant alteration of the C cycle. The interactions between the C and N cycles suggest that rates of C cycling are affected not just by the amount of available N, but also by the relative availability for plant uptake of NH ₄ ⁺ and NO ₃ ⁻ .     

Inhibition of Human Embryonic Cell Cultured Growth by Sodium Salicylate

Because salicylates have been found to reduce the growth rate of cells of the human McCoy cell line (ref. 1 and unpublished results of T. F. Paine) and because they may be consumed in large quantities by women during early pregnancy², we decided to examine their effects on human embryonic cells.     

Assimilation of Inorganic Nitrogen by Marine Invertebrates and Their Chemoautotrophic and Methanotrophic Symbionts

Symbioses between marine invertebrates and their chemoautotrophic and methanotrophic symbionts are now known to exist in a variety of habitats where reduced chemical species are present. The utilization of chemical energy and reliance on C₁ compounds by these symbioses are well documented. Much less is known about their metabolism of nitrogen. Earlier work has shown that the tissues of organisms in these associations are depleted of ¹⁵N compared with those of other marine organisms, indicating that local sources of nitrogen are assimilated and that novel mechanisms of nitrogen metabolism may be involved. Although these symbioses have access to rich sources of ammonium (NH₄⁺ and NH₃) and/or nitrate, several investigators have proposed that N₂ fixation may account for some of these isotope values. Here we report that [¹⁵N]ammonium and, to a lesser degree, [¹⁵N]nitrate are assimilated into organic compounds by Solemya reidi, a gutless clam containing S-oxidizing bacteria, and seep mussel Ia, an undescribed mytilid containing methanotrophic bacteria. In contrast, Riftia pachyptila, the giant hydrothermal vent tube worm symbiotic with S-oxidizing bacteria, assimilated nitrate but not exogenous ammonium. The rates of assimilation of these sources are sufficient to at least partially support C₁ compound metabolism. N₂ assimilation was not exhibited by the symbionts tested.     

Inhibition of Nitrification in the Activated Sludge Process of Sewage Disposal

S ummary . A simple method is described for determining the short term effects of sewages, effluents and individual substances on the nitrifying ability of activated sludge and the results of screening many substances are listed. The effects of mixtures of inhibitors and the possibility of formation of complexes between some of those inhibitors were investigated. The long term effects of inhibitors often differ from their immediate effects, one of the most important factors being the ability of activated sludge to become adapted to the inhibitor.     

Production of Nitrous Oxide by Ammonia-Oxidizing Chemoautotrophic Microorganisms in Soil

Gas chromatographic studies showed that nitrous oxide was produced in each instance when sterilized (autoclaved) soil was incubated after treatment with ammonium sulfate and inoculation with pure cultures of ammonia-oxidizing chemoautotrophic microorganisms (strains of Nitrosomonas, Nitrosospira, and Nitrosolobus). Production of N₂O in ammonium-treated sterilized soil inoculated with Nitrosomonas europaea increased with the concentration of ammonium and the moisture content of the soil and was completely inhibited by both nitrapyrin and acetylene. Similar effects of nitrapyrin, acetylene, ammonium concentration, and soil moisture content were observed in studies of factors affecting N₂O production in nonsterile soil treated with ammonium sulfate. These observations support the conclusion that, at least under some conditions, most of the N₂O evolved from soils treated with ammonium or ammonium-producing fertilizers is generated by chemoautotrophic nitrifying microorganisms during oxidation of ammonium to nitrite.     

Chlorate as a Transport Analog for Nitrate Absorption by Roots of Tomato

Several studies have indicated that chlorate (ClO3-) and nitrate (NO3-) may share a common transport system in higher plants. Here, we compared the interactions between ClO3- and NO3-uptake by roots of intact tomato (Lycopersicon esculentum cv T5) plants. Exposure to ClO3- for more than 2 h inhibited both net ClO3- and K+ uptake, presumably because of ClO3- toxicity; consequently, subsequent measurements were conducted after short exposures to ClO3-. The apparent affinity and apparent maximum rate of absorption for net ClO3- and NO3- uptake were very similar. Interactions between ClO3- and NO3- transport were complex; 50 [mu]M NO3- acted as a mixed inhibitor of net ClO3- uptake, but 50 [mu]M ClO3- had no significant effect on net NO3- uptake, and 500 [mu]M ClO3- had no significant effect on 15NO3- influx. If the two ions share a single common high-affinity transport system, it is much more selective for NO3- than would be suggested by the similarity of net NO3- and ClO3- uptake kinetics. Our results indicate that, although NO3- may interfere with root ClO3- uptake, ClO3- is not a useful analog for the root high-affinity NO3- transport system.