Resistance ofStreptomyces felleus to the herbicide bromoxynil

A soil strain ofStreptomyces felleus resistant to the herbicide bromoxynil (BX) and capable of supporting growth of sensitive streptomycetes on a BX-containing medium, was found to decrease the concentration of BX in the medium to one half after 10 d of incubation. Physicochemical methods showed that a co-metabolic process without any accumulation of the degradation products similar to BX was involved. Mutation experiments carried out with the strain suggest a nonchromasomal control of the resistance to BX.     

Degradation of bromoxynil byStreptomyces felleus in soil

The completein vivo degradation of the herbicide bromoxynil byStreptomyces felleus and soil microorganisms was investigated. Little breakdown occurred in sterile soil. TLC techniques were used to detect two degradation products in non-sterile soil. Authors are obliged to Mrs. E. Chrastinová for technical assistance.     

Unique cellular effect of the herbicide bromoxynil revealed by electrophysiological studies using characean cells

In a previous paper, we proposed that the primary action of the herbicide bromoxynil (BX; 3,5-dibromo-4-hydroxybenzonitrile) is cytosol acidification, based on the fact that bromoxynil induced the inhibition of cytoplasmic streaming and cell death of Chara corallina in acidic external medium (Morimoto and Shimmen in J Plant Res 121:227–233, 2008). In the present study, electrophysiological analysis of the BX effect was carried out in internodal cells of C. corallina. Upon addition of BX, a large and rapid pH-dependent depolarization was induced, supporting our hypothesis. Ioxynil, which belongs to the same group as bromoxynil, also induced a large and rapid membrane depolarization in a pH-dependent manner. On the other hand, four herbicides belonging to other groups of herbicides did not induce such a membrane depolarization. Thus, BX has a unique cellular effect. The decrease in the electro-chemical potential gradient for H⁺ across the plasma membrane appears to result in inhibition of cell growth and disturbance of intracellular homeostasis in the presence of BX.     

Primary effect of bromoxynil to induce plant cell death may be cytosol acidification

Bromoxynil, 3,5-dibromo-4-hydroxybenzonitrile, is a commonly used herbicide and is also used as a tool to trigger rapid cell death in basic botany. However, the primary effect inducing cell death is not known. Bromoxynil inhibited the cytoplasmic streaming and killed cells in Chara corallina when it was applied in the acidic external medium. At higher pH, bromoxynil was inert even at high concentrations. It was speculated that bromoxynil in the protonated form enters the cell and acidifies the cytosol by releasing H⁺. Experiments using analogues of bromoxynil supported this possibility. Acidification of the cytosol by bromoxynil was confirmed by experiments using pollen tubes. Based on the acidity of the apoplast, the herbicide action of bromoxynil in higher plants was discussed.     

Enzymic degradation of bromoxynil by cell-free extracts ofStreptomyces felleus

A method is described for spectrophotometric monitoring the degradation of the herbicide bromoxynil by cell-free extracts of Streptomyces felleus. The method involves a decrease in absorbance at 286 nm (absorption maximum of bromoxynil) that can be ascribed most probably to the cleavage of the aromatic ring of the bromoxynil molecule. Conditions necessary for measuring this degradation together with physico-chemical features of the degradation indicate that the reaction(s) is seemingly catalyzed by an Fe2+-dependent dioxygenase whose activity was not, however, detected in cell-free extracts of a bromoxynil-sensitive mutant of S. felleus as well as other bromoxynil-sensitive streptomycete strains.     

Decomposition of the herbicide bromoxynil in soil and in bacterial cultures

It was found in field, and laboratory experiments that of 50 ppm of the herbicide bromoxynil (3,5-dibromo-4-hydroxybenzonitrile added to grey forest soil 20-80% were still detected after three months). Bromoxynil did not influence (except for a short-termed stimulation of the number of bacteria) the amount and composition of the basic groups of soil microorganisms. In enrichment cultures of soil microorganisms metabolie products of bromoxynil decomposition (3,5-dibromo-4-hydroxybenzamide and 3,5-dibromo-4-hydroxybenzoic acid) were detected and a stimulating effect of cosubstratos on its decomposition was demonstrated. Bromoxynil concentration, aeration conditions and the presence of cosubstrates (ribose in particular) influenced the rate and degree of the decomposition process inPsevdomonas putida. In addition to the degradation products mentioned above, production of methoxylated and partially dehalogenated aromatic compounds was detected.     

The degradation of the herbicide bromoxynil and its impact on bacterial diversity in a top soil

Aims: To study how repeated applications of an herbicide bromoxynil to a soil, mimicking the regime used in the field, affected the degradation of the compound and whether such affects were reflected by changes in the indigenous bacterial community present. Methods and Results: Bromoxynil degradation was monitored in soil microcosms using HPLC. Its impact on the bacterial community was determined using denaturing gradient gel electrophoresis (DGGE) and quantitative PCR of five bacterial taxa (Pseudomonads, Actinobacteria, α‐Proteobacteria, Acidobacteria and nitrifying bacteria). Three applications of 10 mg kg^?1 of bromoxynil at 28‐day intervals resulted in rapid degradation, the time for removal of 50% of the compound decreasing from 6·4 days on the first application to 4·9 days by the third. Bacterial population profiles showed significant similarity throughout the experiment. With the addition of 50 mg kg^?1 bromoxynil to soil, the degradation was preceded by a lag phase and the time for 50% of the compound to be degraded increased from 7 days to 28 days by the third application. The bacterial population showed significant differences 7 days after the final application of bromoxynil that correlated with an inhibition of degradation during the same period. Conclusions: These analyses highlighted that the addition of bromoxynil gave rise to significant shifts in the community diversity and its structure as measured by four abundant taxa, when compared with the control microcosm. These changes persisted even after bromoxynil had been degraded. Significance and Impact of the Study: Here we show that bromoxynil can exert an inhibitory effect on the bacterial population that results in decreased rates of degradation and increased persistence of the compound. In addition, we demonstrate that molecular approaches can identify statistically significant changes in microbial communities that occur in conjunction with changes in the rate of degradation of the compound in the soil.     

乳酸乳球菌表达重组牛乳铁蛋白肽的抑菌活性分析

牛乳铁蛋白肽是由牛乳铁蛋白经消化酶水解产生的一类具有广谱抑菌活性的短肽;乳酸乳球菌作为食品级微生物,既有天然的益生作用,又是理想的表达牛乳铁蛋白肽的载体。【目的】探究重组乳酸乳球菌pAMJ399-LFcinBA/MG1363表达牛乳铁蛋白肽的抑菌活性。【方法】利用牛乳铁蛋白肽标准品绘制定量标准曲线来确定重组牛乳铁蛋白肽的含量,利用牛津杯法及微量肉汤稀释法测定重组牛乳铁蛋白肽对大肠杆菌、金黄色葡萄球菌等35株细菌的抑菌活性及最小抑菌浓度,利用扫描电镜、透射电镜、荧光显微镜、凝胶阻滞试验、黏附试验来探究重组牛乳铁蛋白肽对菌体结构、细菌DNA及黏附力的影响,利用CCK-8检测其对RAW 264.7细胞的毒性作用,并对小鼠红细胞溶血率进行测定。【结果】重组乳酸乳球菌上清中牛乳铁蛋白肽的浓度为24.39μg/mL,重组牛乳铁蛋白肽对测试的25株致病菌均有不同程度的抑制作用,抑菌浓度范围在16–128μg/mL,但对9株乳酸菌以及粪肠球菌没有明显的抑制作用,对大肠杆菌、金黄色葡萄球菌、多杀性巴氏杆菌、鸡白痢沙门菌的菌体完整性具有不同程度的破坏作用,其主要作用靶点为细菌的细胞膜,可以与细菌DNA结合...     

Degradation of the herbicide bromoxynil inPseudomonas putida

Biological conversion of the herbicide bromoxynil (3,5-dibromo-4-hydroxybenzonitrile) was studied in a batch culture ofPseudomonas putida by using HPLC. The process had a cometabolic character and proceeded only in the presence of another, simultaneously metabolizable, carbon and energy source. The intensity of degradation correlated with the growth rate, the degradation stopping when the cosubstrate becomes exhausted or the pH value of the medium falls below 6.5. In a medium with glucose, no lag phase longer than one day was observed concerning growth, sugar and herbicide consumption and formation of metabolic herbicide derivatives (3,5-dibromo-4-hydroxybenzamide and 3,5-dibromo-4-hydroxybenzoic acid). In a medium with ribose, the initial lag of the above processes took 2 d. No formation of other degradation products was detected. Growth inhibition was proportional to the concentration of bromoxynil. Translated by Č. Novotny     

The Uptake of Cytokinins by Protoplasts and Root Sections of Brassica campestris

The effect of cytokinins was studied on the incorporation of ¹⁴C-labelled precursors into the nucleic acid fraction of protoplasts isolated from callus or roots of Brassica campestris. Protoplasts from callus and roots took up ¹⁴C-uridine from the incubation medium and incorporated this precursor into the ribonucleic acid fraction during the experimental period of 16 h. Low concentrations of kinetin (10^?8-5 × 10^?6M) did not stimulate the incorporation, and kinetin inhibited this process at higher concentrations (5 × 10^?5M). This result led to an investigation on the uptake of cytokinins by protoplasts of roots. In contrast to a rapid uptake of radio-actively labelled adenine and uridine. protoplasts from roots took up only small amounts of labelled kinetin. zeatin, zeatin riboside and zeatin nucleotides from the incubation medium. Root sections took up far more adenine and kinetin than protoplasts from roots. The ratio between the amount of kinetin taken up and applied was much higher for the sections than for protoplasts, indicating that intact root cells took up kinetin far more rapidly than protoplasts. It is suggested that the plasmalemma and cell wall play an essential role in the uptake of cytokinins or that the differences in the uptake rates are related to differences between the rates of metabolism of cytokinins in root sections and in protoplasts.     

Development of an in vitro method for the prediction of mycotoxin binding on yeast-based products: case of aflatoxin B1, zearalenone and ochratoxin A

To date, no official method is available to accurately define the binding capacity of binders. The goal is to define general in vitro parameters (equilibrium time, pH, mycotoxin/binder ratio) for the determination of binding efficacy, which can be used to calculate the relevant equilibrium adsorption constants. For this purpose, aflatoxin B₁ (AFB₁), zearalenone (ZEA) or ochratoxin A (OTA) were incubated with one yeast cell wall in pH 3, pH 5 or pH 7 buffers. The percentage of adsorption was recorded by quantitation of remaining mycotoxins in the supernatant and amount of mycotoxin adsorbed on the residue. The incubation of yeast cell wall in the presence of mycotoxins solved in buffer, lead to unexpected high adsorption percentage when the analysis was based only on remaining mycotoxins in the supernatant. The decrease of mycotoxins in the supernatant was not correlated to the amount of mycotoxins found in the residue. For this reason we modified the conditions of incubation. Yeast cell wall (5 mg) was pre-incubated in buffer (990 μl) at 37 °C during 5 min and then 10 μl of an alcoholic solution of mycotoxin (concentration 100 times higher than the final concentration required in the test tube) were added. After incubation, the solution was centrifuged, and the amount of mycotoxins were analysed both in the supernatant and in the residue. A plateau of binding was reached after 15 min of incubation whatever the mycotoxins and the concentrations tested. The adsorption of ZEA was better at pH 5 (75 %), versus 60 % at pH 3 and 7. OTA was only significantly adsorbed at pH 3 (50 %). Depending on the pH, the adsorptions of OTA or ZEA were increased or decreased when they were together, indicative of a cooperative effect.     

A vector system with temperature-sensitive replication for gene disruption and mutational cloning in streptomycetes

Summary Replication of the Streptomyces ghanaensis plasmid pSG5 was shown to be temperature sensitive. The pSG5 replicon is stably inherited at temperatures below 34° C, but is lost at incubation temperatures above this. A family of cloning vectors was constructed using the pSG5 minimal replicon and different marker genes. The vectors obtained are small in size, have an intermediate copy number, possess a broad host range and are compatible with some other streptomycete vector systems. By increasing the incubation temperature, these vectors can be eliminated from their host cells very efficiently. The suitability of the pSG5 vector family for mutating chromosomal genes by gene disruption was demonstrated: pBN10, a pSG5 derivative containing an internal fragment of the phosphinothricyl-alanyl-alanine (PTT) resistance gene pat, was integrated into the chromosomal pat gene of the PTT-producer Streptomyces viridochromogenes thus inactivating PTT resistance. The integrated pBN10 plasmid was rescued from the chromosome, together with an adjacent fragment carrying DNA of the PTT biosynthetic cluster.     

Uranium and lead accumulation in cells of Streptomyces sp.

Lead and uranium were accumulated equally well both in the viable and dry biomass of Streptomyces sp. The process occurred in less than 5 min. Uranium was accumulated selectively from a polymetallic solution containing U, Pb, Cu, Zn, Ni, Co. The optimum pH for the process was 5.0, and the concentration of each metal in the solution was 10(-3) M. Under these conditions, the dry biomass of Streptomyces amounting to 1 mg/cm3 accumulated over 60% of the uranium in the solution. With the same amount of cell wall preparation it was possible to remove from the solution ca. 90% of U. In this case, the accumulated uranium reached 21% of the sorbent dry mass. Electron micrographs show that lead accumulated in Streptomyces cells is mainly concentrated in the cell wall structures although in the case of uranium this is not so clear.     

INCREASE IN CELL WALL SURFACE AREA DURING ENLARGEMENT OF CAMBIAL DERIVATIVES IN ABIES CONCOLOR

Wilson , Brayton F. (U. California, Berkeley). Increase in cell wall surface area during enlargement of cambial derivatives in Abies eoncolor . Amer. Jour. Bot. 50(1): 95–102. Illus. 1963.— Dimensions of fusiform cells (tracheids and sieve cells) and ray cells were measured from samples of the 1960 xylem and phloem increment of 5 trees felled at monthly intervals from April through July, 1960. Calculations using these measurements gave the magnitude, direction and rate of increase in cell wall surface area during enlargement. Although 14 times more tracheids than sieve cells were produced, both cell types enlarged mostly in a radial direction (up to 400%) at the same rate (20–33 × 10³μ² wall surface area/day) to the same final size. Fusiform cambial cells doubled their wall area between successive periclinal divisions. Calculations showed that ⅞ of this increase was in the radial walls of the daughter cells at a rate comparable to that in enlarging tracheids and sieve cells; the other ⅞ was from cell plate formation at an estimated rate of 187–327 × 10³μ²/day. Enlargement of derivatives in the radial direction largely determined the amount of increase in wall area. Besides radial enlargement, tracheids also elongated (up to 13%) and phloem cells enlarged tangentially (sieve cells up to 36%; pholem ray cells up to 60%). The relationships of enlarging tracheids and xylem ray cells are discussed, and it is suggested that slippage may occur between the developing walls.     

Hydrolysis of benzonitrile herbicides by soil actinobacteria and metabolite toxicity

The soil actinobacteria Rhodococcus rhodochrous PA-34, Rhodococcus sp. NDB 1165 and Nocardia globerula NHB-2 grown in the presence of isobutyronitrile exhibited nitrilase activities towards benzonitrile (approx. 1.1–1.9 U mg^?1 dry cell weight). The resting cell suspensions eliminated benzonitrile and the benzonitrile analogues chloroxynil (3,5-dichloro-4-hydroxybenzonitrile), bromoxynil (3,5-dibromo-4-hydroxybenzonitrile) and ioxynil (3,5-diiodo-4-hydroxybenzonitrile) (0.5 mM each) from reaction mixtures at 30°C and pH 8.0. The products were isolated and identified as the corresponding substituted benzoic acids. The reaction rates decreased in the order benzonitrile ? chloroxynil > bromoxynil > ioxynil in all strains. Depending on the strain, 92–100, 70–90 and 30–51% of chloroxynil, bromoxynil and ioxynil, respectively, was hydrolyzed after 5 h. After a 20-h incubation, almost full conversion of chloroxynil and bromoxynil was observed in all strains, while only about 60% of the added ioxynil was converted into carboxylic acid. The product of ioxynil was not metabolized any further, and those of the other two herbicides very slowly. None of the nitrilase-producing strains hydrolyzed dichlobenil (2,6-dichlorobenzonitrile). 3,5-Dibromo-4-hydroxybenzoic acid exhibited less inhibitory effect than bromoxynil both on luminescent bacteria and germinating seeds of Lactuca sativa. 3,5-Diiodo-4-hydroxybenzoic acid only exhibited lower toxicity than ioxynil in the latter test.     

Isolation and characterization of alachlor-degrading actinomycetes from soil

Alachlor (2-cloro-N-(methoxymethyl)-N-(2,6-diethylphenyl)-acetamide) is an extremely toxic and highly mobile herbicide that is widely used for pre-emergence control of grasses and weeds in many commercial crops in Brazil. In order to select soil actinomycetes able to degrade this herbicide, fifty-three actinomycete strains were isolated from soil treated with alachlor using selective conditions and subjected to in vitro degradation assays. Sixteen isolates were shown to be tolerant to high concentrations of the herbicide (up to 720 mg L^-1), and six of these were able to grow and degrade 50 alachlor (72 mg L^-1) in mineral salts medium. Morphological and phylogenetic analysis enabled the assignment of the alachlor-degrading strains to the genus Streptomyces. Strain LS151 was related to the type strains of Streptomyces capoamus/Streptomyces galbus, whereas strains LS143 and LS153 were related to Streptomyces bikiniensis. The remaining strains, LS166, LS177 and LS182, were similar in morphological features and recovered in a single cluster based on 16S rDNA sequence analysis, but shown to be distinct on the basis of genomic fingerprint data (rep-PCR). Though a definitive taxonomic assignment of alachlor-degrading strains was not possible, these data indicate that ability to degrade this pesticide was detected in different Streptomyces taxa.     

Effect of glucose and ribose on microbial degradation of the herbicide bromoxynil continuously added to soil

Bromoxynil (3,5-dibromo-4-hydroxybenzonitrile) was continuously added to chernozem (Haplic typic) soil inoculated with a suspension ofPseudomonas putida capable of cometabolic decomposition of the compound in a heterocontinuous-flow cultivation setup. In the steady state, when glucose or ribose were simultaneously added, 90 and 47% of the added herbicide was degraded per day, respectively. If the saccharides were absent, only 10–27% of the herbicide was decomposed. Addition and removal of glucose feeding resulted in an increase and decrease, respectively, of the degradation intensity, irrespective of the amount of the bacterial decomposers present. Two degradation products, 3,5-dibromo-4-hydroxy-benzamide and 3,5-dibromo-4-hydroxybenzoic acid, were formed during cultivation. The total amount of bromine-containing compounds was reduced only in the presence of glucose. Translated by Č. Novotny     

Metabolism of the herbicide bromoxynil by Klebsiella pneumoniae subsp. ozaenae.

Enrichment of soil samples for organisms able to utilize the herbicide bromoxynil (3,5-dibromo-4-hydroxybenzonitrile) as a nitrogen source yielded bacterial isolates capable of rapidly metabolizing this compound. One isolate, identified as Klebsiella pneumoniae subsp. ozaenae, could completely convert 0.05% bromoxynil to 3,5-dibromo-4-hydroxybenzoic acid and use the liberated ammonia as a sole nitrogen source. Assays of cell extracts of this organism for the ability to produce ammonia from bromoxynil revealed the presence of a nitrilase (EC 3.5.51) activity. The enzyme could not utilize 3,5-dibromo-4-hydroxybenzamide as a substrate, and no 3,5-dibromo-4-hydroxybenzamide could be detected as a product of bromoxynil transformation. Comparison of related aromatic nitriles as substrates demonstrated that the Klebsiella enzyme is highly specific for bromoxynil.     

Metabolism of the herbicide bromoxynil by Klebsiella pneumoniae subsp. ozaenae

Enrichment of soil samples for organisms able to utilize the herbicide bromoxynil (3,5-dibromo-4-hydroxybenzonitrile) as a nitrogen source yielded bacterial isolates capable of rapidly metabolizing this compound. One isolate, identified as Klebsiella pneumoniae subsp. ozaenae, could completely convert 0.05% bromoxynil to 3,5-dibromo-4-hydroxybenzoic acid and use the liberated ammonia as a sole nitrogen source. Assays of cell extracts of this organism for the ability to produce ammonia from bromoxynil revealed the presence of a nitrilase (EC 3.5.51) activity. The enzyme could not utilize 3,5-dibromo-4-hydroxybenzamide as a substrate, and no 3,5-dibromo-4-hydroxybenzamide could be detected as a product of bromoxynil transformation. Comparison of related aromatic nitriles as substrates demonstrated that the Klebsiella enzyme is highly specific for bromoxynil.     

Plasmolysis as a Tool to Reveal Lead Localization in the Apoplast of Root Cells

In order to analyze the distribution of lead between cell walls and plasmalemma, two-day-old maize seedlings (Zea mays L.) were incubated for 24 h on a solution of lead nitrate at a concentration causing 50% inhibition of root growth (10^–5 M). Using the histochemical technique (precipitation of lead dithizonate), the distribution of lead in plasmolyzed and nonplasmolyzed cells of the root cortex was compared. This allowed us to separate the lead bound by cell walls from the lead located on the protoplast surface and in the periplasmic space. The plasmolysis was conducted prior to histochemical reaction by the incubation of seedling roots in 0.6 M sucrose solution for 30 min. The lead precipitates were located in cell walls and on the surface of protoplast. A small amount of lead was found in periplasmic space of some cells in root cortex. It is suggested that the lead is bound not only to the cell wall matrix but also to the plasmalemma.