AgNO3对大肠杆菌和金黄色葡萄球菌的抗菌作用及机制

以大肠杆菌和金黄色葡萄球菌为模式菌,对AgNO3的抗菌效果进行研究,并对其抗菌机制作初步探讨。AgNO3对大肠杆菌的抑制生长曲线表明:2.891 mg/L的AgNO3能够完全抑制106个/mL的大肠杆菌细胞生长,AgNO3使大肠杆菌和金黄色葡萄球菌的延滞期加长,并且浓度越高,延滞期越长。另外,AgNO3对大肠杆菌和金黄色葡萄球菌脱氢酶的活性有明显影响,随着AgNO3浓度的提高,脱氢酶的活性逐渐降低。AgNO3溶液作用于细菌后,细菌表面疏水性均有不同程度地下降,且浓度越大对其影响也越明显,大肠杆菌的下降程度要大于金黄色葡萄球菌。     

Subsurface Biofilm Barriers for the Containment and Remediation of Contaminated Groundwater

An engineered microbial biofilm barrier capable of reducing aquifer hydraulic conductivity while simultaneously biodegrading nitrate has been developed and tested at a field-relevant scale. The 22-month demonstration project was conducted at the MSE Technology Applications Inc. test facility in Butte, Montana, which consisted of a 130 ft wide, 180 ft long, 21 ft deep, polyvinylchloride (PVC)-lined test cell, with an initial hydraulic conductivity of 4.2 × 10^?2 cm/s. A flow field was established across the test cell by injecting water upgradient while simultaneously pumping from an effluent well located approximately 82 ft down gradient. A 30 ft wide biofilm barrier was developed along the centerline of the test cell by injecting a starved bacterial inoculum of Pseudomonas fluorescens strain CPC211a, followed by injection of a growth nutrient mixture composed of molasses, nitrate, and other additives. A 99% reduction of average hydraulic conductivity across the barrier was accomplished after three months of weekly or bi-weekly injections of growth nutrient. Reduced hydraulic conductivity was maintained by additional nutrient injections at intervals ranging from three to ten months. After the barrier was in place, a sustained concentration of 100 mg/l nitrate nitrogen, along with a 100 mg/l concentration of conservative (chloride) tracer, was added to the test cell influent over a six-month period. At the test cell effluent the concentration of chloride increased to about 80 mg/l while the effluent nitrate concentration varied between 0.0 and 6.4 mg/l.     

Anion Permeability of Frog Skeletal Muscle

Unidirectional chloride effluxes from small bundles of muscle fibers were measured under equilibrium conditions. It was found that chloride effluxes are described by the constant field theory with a chloride permeability constant, P_cl, which is independent of the chloride concentration and the membrane potential. The value of P_cl at neutral pH was found to be 5 x 10^-6 cm/sec. Chloride movements were markedly depressed at low pH and increased at high pH. It is concluded that chloride fluxes are independent of each other over a wide pH range. The effect of nitrate on the chloride effluxes was measured. It was found that both external and internal nitrate alone reduced the chloride efflux with the external nitrate appearing more effective than internal nitrate due to the nonequilibrium nature of the experimental conditions. Under equilibrium conditions the reduction of the chloride efflux by nitrate was greater than the external nitrate effect, both of which were dependent on the relative proportion of nitrate in the bathing solution. These results are consistent with the hypothesis that the inhibition of the chloride movements by nitrate is essentially symmetrical with regard to the inside and outside surfaces of the muscle membranes. The relative action of nitrate on the chloride efflux was independent of the external pH despite marked changes in the absolute values of the fluxes measured.     

Subsurface Biofilm Barriers for the Containment and Remediation of Contaminated Groundwater

An engineered microbial biofilm barrier capable of reducing aquifer hydraulic conductivity while simultaneously biodegrading nitrate has been developed and tested at a field-relevant scale. The 22-month demonstration project was conducted at the MSE Technology Applications Inc. test facility in Butte, Montana, which consisted of a 130 ft wide, 180 ft long, 21 ft deep, polyvinylchloride (PVC)-lined test cell, with an initial hydraulic conductivity of 4.2 × 10^-2 cm/s. A flow field was established across the test cell by injecting water upgradient while simultaneously pumping from an effluent well located approximately 82 ft down gradient. A 30 ft wide biofilm barrier was developed along the centerline of the test cell by injecting a starved bacterial inoculum of Pseudomonas fluorescens strain CPC211a, followed by injection of a growth nutrient mixture composed of molasses, nitrate, and other additives. A 99% reduction of average hydraulic conductivity across the barrier was accomplished after three months of weekly or bi-weekly injections of growth nutrient. Reduced hydraulic conductivity was maintained by additional nutrient injections at intervals ranging from three to ten months. After the barrier was in place, a sustained concentration of 100 mg/l nitrate nitrogen, along with a 100 mg/l concentration of conservative (chloride) tracer, was added to the test cell influent over a six-month period. At the test cell effluent the concentration of chloride increased to about 80 mg/l while the effluent nitrate concentration varied between 0.0 and 6.4 mg/l.     

The effect of aluminium on the heam biosynthesis (in vitro) in bone marrow cells in rats.

The study has been carried out on male Wistar rats. The aim of the present study was to trace the effect of aluminium chloride and aluminium nitrate at concentration 10 microM and 20 microM on haem biosynthesis in vitro in bone marrow cell culture. The ability of haem biosynthesis in bone marrow cell culture after 48 h of experiments with aluminium chloride and aluminium nitrate significantly decreased in relation with the control value.     

The effect of chloride on nitrate reductase level,on anaerobic nitrite production,and on nitrate content in excisedPisum sativum L. roots

The effect was studied of chloride ions, added in the form of different salts, on nitrate reductase (NR) level in excised pea roots, on anaerobic nitrite production in an assay medium lacking both nitrate and n-propanol, on nitrate content in the roots, and on in vivo NR activity determined in an assay medium containing 5% n-propanol. The presence of Cl in nitrate containing nutrient solutions resulted in lower NR levels, however counterions supplied together with Cl tended to modify slightly this general trend. The negative effect of Cl ions was also apparent, when Cl ions were applied before nitrate ions. Anaerobic nitrite production in the medium lacking both nitrate and n-propanol was not influenced by chloride ions. Nitrate content in the roots was reduced in the presence of chloride both at 3 mM and 15 mM NO₃ in nutrient solutions; however, at 16 mM NO₃, nitrate content in the roots exoeeded even in the presence of 15 mM Cl nitrate content in those root segments which were cultivated in a nutrient solution with 6 mM nitrate, which is the concentration at which NR reaches the level of saturation in excised pea roots. The results obtained suggest that a special induction nitrate pool exists in plant cells besides the storage and metabolic nitrate pools.     

Ion exchange membrane bioreactor for selective removal of nitrate from drinking water: control of ion fluxes and process performance

An ion exchange membrane bioreactor (IEMB), consisting of a monoanion permselective membrane dialyzer coupled to a stirred anoxic vessel with an enriched mixed denitrifying culture, has been studied for nitrate removal from drinking water. The influence of nitrate and chloride concentrations on the selectivity of nitrate transport in the IEMB process was investigated. With appropriate dosing of chloride ions to the IEMB biocompartment, it was possible to regulate the net bicarbonate flux in the system, thus maintaining the bicarbonate concentration in the treated water at the desired level. The latter was not possible to achieve in Donnan dialysis, operated as a single process in which, besides the lower nitrate removal efficiency found, bicarbonate was co-extracted together with nitrate from the polluted water stream. Residual carbon source (ethanol) and nitrite were not detected in the treated water produced in the IEMB system. With a concentration of nitrate in the polluted water three times higher than the maximum contaminant level of 50 mg L(-1) allowed, the IEMB process was successfully operated for a period of 1 month before exceeding this limit.     

Conductometric analysis of the competition between monovalent and divalent counterions in their interaction with polyelectrolytes

A procedure is described for the analysis of the conductivity of solutions of anionic polyelectrolytes in which both mono- and divalent counterions are present. The method is based on analysis of the relation between the overall conductivity of the system and the conductivity of the individual monovalent cations which are only electrostatically (non-specifically) bound. The system is described in terms of the two-state approach, implying that the counterions are considered to be either fully bound to the polyion or completely free. The potentialities of the proposed method are explored by studying solutions of alkali polyacrylates with and without added zinc nitrate at several alkali nitrate concentrations. The results give a picture of the composition of the counterionic atmosphere around the polyion in systems with both mono- and divalent counterions present. To a certain degree, the divalent ion Zn(II) was found to be bound quantitatively by the polyion. The composition of the counterionic atmosphere around the polyion was largely independent of alkali nitrate concentration when the latter was present in not too large an excess with respect to both Zn(II) and the charged monomers.     

Effects of NaCl salinity on 15N-nitrate fluxes and specific root length in the halophyte Plantago maritima L.

The effect of salinity on nitrate influx, efflux, nitrate net uptake rate and net nitrogen translocation to the shoot was assessed in a ¹⁵N steady state labelling experiment in the halophyte Plantago maritima L. raised for 14 days on solution supplied with 50, 100 and 200 mol m^–3 sodium chloride or without sodium chloride. Additionally, salinity induced changes in root morphology were determined. Specific root length increased upon exposure to elevated sodium chloride concentrations due to variations in biomass allocation and length growth of the tap root. Changes in root morphology, however, had a minor effect on nitrate fluxes when expressed on a root fresh weight basis. The decreased rate of nitrate net uptake in plants grown on elevated levels of sodium chloride was almost entirely due to a decrease in nitrate influx. Expressed as a proportion of influx, nitrate efflux remained unchanged and was even lower at the highest salinity level. At all sodium chloride concentrations applied the initial rate of nitrogen net translocation to the shoot decreased relative to the rate of nitrate net uptake. It is concluded that under steady state conditions the negative effect of sodium chloride on the rate of nitrate net uptake at non growth-limiting salinity levels was due to the interaction between sodium chloride and nitrate transporters in the root plasma membrane and/or processes mediating the translocation of nitrogen compounds, possibly nitrate, to the shoot.     

Current voltage curves of biomolecular lipid membranes.

The first part of this paper describes the current voltage curves of bimolecular membranes of oxidized cholesterol formed between two aqueous solutions of tetrabutylammonium chloride. These membranes are selectively permeable for cations and the membrane interfaces are electrically uncharged. The dependence of the membrane conductivity on the membrane potential can be described as the product of the conductivity at zero current ("zero conductivity") and a function called "overlinearity". The zero conductivity increases linearly with the concentration of tetrabutylammonium chloride. The overlinearity is independent of the concentration of tetrabutylammonium chloride. In the second part the Nernst-Planck and Poisson equations are integrated numerically for a three-phase system consisting of an aqueous electrolyte solution, a membrane and an aqueous electrolyte solution. Each phase is characterized by material constants. Appropriate boundary conditions cause the electric current to build up electrical double layers on both sides of the membrane. The opposing double layers with opposite electrical signs inject the soluble ions into the membrane. This ion injection accounts for the overlinearity of the current voltage curves, thus explaining the measured characteristics.     

THE ACCUMULATION OF ELECTROLYTES : XII. ACCUMULATION OF HALIDE AND NITRATE BY VALONIA IN HYPERTONIC SOLUTIONS

When cells of Valonia macrophysa were placed in hypertonic sea water, the concentration of halide and of nitrate increased, and the sum of halide + nitrate became 0.05 M greater inside than outside, which is about the same difference as is found in cells in normal sea water. In ordinary sea water the ratio of halide to nitrate is 80,000 to 1. When this was changed by substituting nitrate for halide so that the concentration of halide was 1.75 times that of nitrate the rate of entrance of halide was 1.68 times that of nitrate in 276 hours and the ratio of halide to nitrate in the sap decreased from 38 to 18.5. No halide came out in exchange for entering nitrate. The retention of chloride may well be due to the fact that even when the halide concentration of the sea water is reduced as low as 0.4 M, there is still an inwardly directed activity gradient of sodium chloride.     

The transport of chloride in Ehrlich ascites tumor cells.

The steady state transport and distribution of chloride between the intracellular and extracellular phases was investigated when the extracellular chloride concentration was varied by isosmotic replacement with nitrate, bromide and acetate. The results of these experiments show that chloride transport, measured by uptake of 36Cl, is sensitive to the replacement anion. In the presence of nitrate, chloride transport is a linear function of the extracellular chloride concentration. The relationship between chloride transport and extracellular chloride in the presence of bromide is concave upward which suggests that this anion inhibits chloride movement. However, when acetate replaces chloride, the relationship between chloride transport and extracellular chloride is concave downward. The chloride distribution ratio of cells incubated in 145-155mM chloride medium is 0.386 and is not effected by the replacement of chloride with nitrate, bromide or acetate. These findings are consistent with the assertion that chloride transport is composed of two parallel pathways, a diffusional plus a saturating, mediated component. Of the total chloride flux (9.1 mmoles Cl-/kg dry weight per minute) measured in chloride medium (145-155 mM Cl-), the mediated component represents 40% and the diffusional component 60%.     

秦皮素对大肠埃希菌作用机制的初步研究

目的以大肠埃希菌ATCC 25922为供试菌,探讨秦皮素的抑菌活性及其作用机制。方法利用TTC法测定秦皮素对大肠埃希菌ATCC 25922的最低抑菌浓度;通过测定加药前后菌体培养液电导率和大分子的变化及观察扫描电镜和透射电镜电镜结果,分析秦皮素对其细胞膜的影响;通过SDS-PAGE测定秦皮素对供试菌株蛋白含量的影响;采用逐个检出法研究秦皮素对大肠埃希菌ATCC 25922质粒合成的抑制作用。结果秦皮素可抑制大肠埃希菌ATCC 25922的生长,其最低抑菌浓度为40μg/mL。秦皮素作用菌体5 h后,培养液中的电导率比对照组增加1.96%,但DNA和RNA大分子增加的不明显。秦皮素作用大肠埃希菌20 h后,菌体可溶性蛋白总量比对照组降低42%。秦皮素对大肠埃希菌的质粒有消除作用,药物作用48 h后,秦皮素对大肠埃希菌的质粒消除率为60.3%。结论秦皮素可抑制大肠埃希菌的生长,其抑菌作用机制与抑制菌体内蛋白质合成和消除菌体内的质粒有关,但对大肠埃希菌细胞膜的影响不大。     

Decrease in nitrate reductase activity in extracts of Trichoderma viride Incubated with chlorides.

Reduced nicotinamide adenine dinucleotide phosphate-dependent nitrate reductase activity in crude extracts of Trichoderma virde was significantly inhibited by physiological concentrations of ammonium chloride, sodium chloride, and potassium chloride, but not by ammonium or sodium sulfate. The chloride inhibition of nitrate reductase activity increased in a linear manner with chloride concentration.     

The Effects of Changes in the Inorganic Nitrogen Supply on the Growth and Development of Marsilea in Aseptic Culture

The effects of changes in the inorganic nitrogen source of themedium on the growth and development of Marsilea in asepticculture are described. A change in nitrate concentration to0·2 or 5 x that of the normal medium had initially noeffect on growth or heteroblastic development, but in the 0·2nitrogen medium there was finally a reversion to juvenile stagesfollowed by early cessation of growth. Growth and heteroblastic development were stimulated by thesubstitution of the nitrate of the medium by ammonium saltsor urea. Nitrite was little inferior to nitrate as a nitrogensource, but hydroxylamine was toxic even at low concentrations.Addition of sodium chloride led to improved growth and developmentin nitrate media, an effect referred to beneficial effects ofthe chloride ion. Symptoms of toxicity and eventual death of the cultures whichoccurred after prolonged growth on ammonium media were due toan acid drift of the media rather than to a specific effectof the ammonium ion.     

The binding of nitrate to the human anion exchange protein (AE1) studied with 14N nuclear magnetic resonance

The binding of [14N]nitrate to the human erythrocyte anion transport protein, AE1, was studied using 14N nuclear magnetic resonance spectroscopy (14N-NMR). The line-width at half-height of the 14NO3- resonance increased in direct proportion to the concentration of erythrocyte ghost protein. Addition of the AE1 specific inhibitor 4,4'-dinitrostilbene-2,2'-disulfonate markedly reduced this line-broadening, indicating that the broadening was predominantly due to a specific interaction between nitrate and AE1. The dependence of the AE1 specific line-broadening on nitrate concentration had a first-order dissociation constant KD of 6.9 +/- 0.9 mM. In contrast, Cl- interaction with AE1 studied by 35Cl-NMR showed a chloride concentration-dependent line-broadening with a KD of 74 +/- 10 mM, indicating that AE1 has a higher affinity for nitrate than for chloride. Bicarbonate and chloride were found to be competitive inhibitors of the AE1 specific 14NO3- line-broadening (94 +/- 6% and 101 +/- 3% inhibition, respectively). Based on the concentration dependence of inhibition and using a model of competitive inhibition, the KD of bicarbonate binding to AE1 was estimated to be 5.4 +/- 1.3 mM. Nitrate is a structural analog of bicarbonate, making the interaction of nitrate with AE1 a good model for the bicarbonate-AE1 interaction. The 14N-NMR nitrate binding assay, along with the 35Cl-NMR binding assay now in use, will provide a powerful tool for studying the structure of the AE1 binding site for both physiologic substrates, bicarbonate and chloride.     

Bilateral sweat tests with two different methods as a part of cystic fibrosis newborn screening (CF NBS) protocol and additional quality control

Infants with positive CF newborn screening (NBS) results are called to a CF Centre for verification. Those, in whom the sweat test is elevated, undergo further medical procedures. The aim of our study was to evaluate the applicability of Nanoduct - a new system measuring sweat conductivity and giving immediate results in a CF NBS protocol. Measurements with Nanoduct were compared with the classic pilocarpine method. During 3 years 487 infants from CF NBS had both sweat tests performed on the same day, at the same CF centre. CF infants had a mean conductivity of 99.8 ± 1 8.8 mmol/L and a mean chloride concentration of 74.0 ± 18.4 mmol/L. Non-CF infants values were 29.8 ± 7.7 mmol/L and 19.2 ± 6.6 mmol/L respectively. A good correlation between both tests was found (95% confidence level (CI); r=0.87). The optimal cut off, based on follow up experience of screened children, for conductivity tests was 50 mmol/L and for chloride concentration was 34 mmol/L (no lost CF, 11 false positive) with 100% sensitivity and 97.5 % specificity. In conclusion Nanoduct is a very useful and reliable tool in CF NBS protocol, allowing more time efficient organization of the diagnostic and training procedures. Simultaneous bilateral sweat testing with two different methods (concentration and conductivity) provides an extra quality control system.     

Effect of osmolarity on potassium transport in isolated cerebral microvessels

Potassium transport in microvessels isolated from rat brain by a technique involving density gradient centrifugation was studied in HEPES buffer solutions of varying osmolarity from 200 to 420 mosmols, containing different concentration of sodium chloride, choline chloride, or sodium nitrate. The flux of 86Rb (as a tracer for K) into and out of the endothelial cells was estimated. Potassium influx was very sensitive to the osmolarity of the medium. Ouabain-insensitive K-component was reduced in hypotonic medium and was increased in medium made hypertonic with sodium chloride or mannitol. Choline chloride replacement caused a large reduction in K influx. Potassium influx was significant decrease when nitrate is substituted for chloride ion in isotonic and hypertonic media, whereas a slight decrease was found in hypotonic medium. The decrease of K influx in the ion-replacement medium is due to a decrement of the ouabain-insensitive component. Potassium efflux was unchanged in hypotonic medium but was somewhat reduced in hypertonic medium. The marked effect of medium osmolarity on K fluxes suggests that these fluxes may be responsible for the volume regulatory K movements. The possible mechanism of changes of K flux under anisotonic media is also discussed.     

The change from symmetry to asymmetry of a sodium transport system in red cell membranes

A study has been made with human red cells of sodium movements that are sensitive to the drug furosemide. The aim was to see if furosemide-sensitive movements that are symmetrical (exchange) became asymmetrical (net transport) on replacement of chloride with nitrate as the major external anion. Cells were incubated for 4 h at 37 degrees C with 140 mM sodium, and chloride or nitrate as the principal anion. Under a variety of conditions (presence and absence of ouabain or furosemide, or both) the cell sodium concentration was always higher when chloride was replaced with nitrate. The cells became leakier to sodium. Tracer studies indicated that, in contrast to the results in chloride medium, the decrease in sodium influx was greater than the fall in efflux when furosemide was added to cells in nitrate medium. The results confirm that the sensitivity of sodium efflux to furosemide depended on chloride. However, influx showed a different sensitivity in that furosemide still inhibited in cells incubated in nitrate medium. The stimulation of sodium influx with nitrate medium was independent of external potassium (10-50 mM) and the furosemide-sensitive influx was also constant. It is concluded that symmetrical transmembrane sodium movements with cells in chloride medium became downhill asymmetrical in nitrate medium, giving a net gain of cell sodium that was insensitive to ouabain and sensitive to furosemide. The drug thus partly retarded the gain of cell sodium that otherwise occurred in the somewhat leaky cells.     

Stimulation of sugar loading into sieve elements of willow by potassium and sodium salts

Potassium as the chloride, nitrate or sulphate or sodium as the chloride, were applied at a concentration of 50 mM either to the xylem of stem segments or to the cambial surface of bark strips of willow. Potassium chloride increased the concentration of sucrose in sieve tube exudate collected via severed aphid stylets, without significantly affecting the volume flow rate, or the concentration of potassium in the exudate. The increase in the sucrose level in the sieve tube sap was shown to be due to a stimulation of loading, rather than to an enhancement of longitudinal transport. Potassium nitrate and sulphate or sodium chloride, were not as effective as potassium chloride in stimulating the loading of sucrose. It is suggested that uptake of the cation into cells supplying sugars to the sieve tube is linked to the rate of release of sugars by the supplying cells.