Mercury detoxifying enzymes within endospores of a broad-spectrum mercury resistantBacillus pasteurii strain DR2

Bacillus pasteurii DR₂, a broad-spectrum Hg-resistant bacterial strain, exhibited delayed sporulation and less mercury volatilization in the presence of mercury compounds. However, Hg-sensitiveBacillus subtilis sporulated quickly in the presence of HgCl₂ and volatilized no mercury. Levels of Hg²⁺-reductase and organomercurial lyase in the endospores ofBacillus pasteurii DR₂ were lower than those in vegetative cells     

Removal of mercury from chloralkali electrolysis wastewater by a mercury-resistant Pseudomonas putida strain

A mercury-resistant bacterial strain which is able to reduce ionic mercury to metallic mercury was used to remediate in laboratory columns mercury-containing wastewater produced during electrolytic production of chlorine. Factory effluents from several chloralkali plants in Europe were analyzed, and these effluents contained total mercury concentrations between 1.6 and 7.6 mg/liter and high chloride concentrations (up to 25 g/liter) and had pH values which were either acidic (pH 2.4) or alkaline (pH 13.0). A mercury-resistant bacterial strain, Pseudomonas putida Spi3, was isolated from polluted river sediments. Biofilms of P. putida Spi3 were grown on porous carrier material in laboratory column bioreactors. The bioreactors were continuously fed with sterile synthetic model wastewater or nonsterile, neutralized, aerated chloralkali wastewater. We found that sodium chloride concentrations up to 24 g/liter did not inhibit microbial mercury retention and that mercury concentrations up to 7 mg/liter could be treated with the bacterial biofilm with no loss of activity. When wastewater samples from three different chloralkali plants in Europe were used, levels of mercury retention efficiency between 90 and 98% were obtained. Thus, microbial mercury removal is a potential biological treatment for chloralkali electrolysis wastewater.     

The meroperon of a mercury-resistant Pseudoalteromonas haloplanktis strain isolated from Minamata Bay, Japan

A mer operon of mercury-resistant Pseudoalteromonas haloplanktis strain M1, isolated from sea water of Minamata Bay, was cloned and analyzed. The mer genes were located in the chromosome and organized as merR-merT-merP-merC-merA-merD, the same order as that in Tn21. However, the orientation of the merR gene is the same as that of other mer genes (opposite direction to Tn21), and merR was cotranscribed with other mer genes, a pattern that has not been previously seen with mer determinants from other Gram-negative bacteria. Furthermore, the amino acid similarities of the corresponding mer gene products between those from strain M1 and Tn21 were unusually low.     

Studies on exocellular hydrolases from a new Penicillium ulaiense strain

A new Penicillium ulaiense strain showed carboxymethylcellulase, pectinase, protease on skim milk and naringinase activities, but no xylanase, cellulase, lipase, amylase, protease on gelatin, and ligninase activities. Studies in liquid medium showed low quantities of pectinases. No mycotoxins were detected.     

Cadmium- and mercury-resistant Bacillus strains from a salt marsh and from Boston Harbor

Bacteria resistant to cadmium or mercury or both were isolated from the Great Sippewissett Marsh (Cape Cod, Mass.) and from Boston Harbor. Many of these metal-resistant isolates were gram-positive aerobic sporeformers, although not necessarily isolated as spores. Although several of the isolated strains bore plasmids, cadmium and mercury resistances appeared to be, for the most part, chromosomally encoded. DNA sequence homology of the gram-positive cadmium- and mercury-resistant isolates was not demonstrable with metal resistance genes from plasmids of either gram-positive (pI258) or gram-negative (pDB7) origin. Cadmium resistance of all the marsh isolates tested resulted from reduced Cd2+ transport. On the other hand, three cadmium-resistant harbor isolates displayed considerable influx but no efflux of Cd2+. Hg-resistant strains detoxified mercury by transforming Hg2+ to volatile Hg0 via mercuric reductase.     

Cadmium- and mercury-resistant Bacillus strains from a salt marsh and from Boston Harbor.

Bacteria resistant to cadmium or mercury or both were isolated from the Great Sippewissett Marsh (Cape Cod, Mass.) and from Boston Harbor. Many of these metal-resistant isolates were gram-positive aerobic sporeformers, although not necessarily isolated as spores. Although several of the isolated strains bore plasmids, cadmium and mercury resistances appeared to be, for the most part, chromosomally encoded. DNA sequence homology of the gram-positive cadmium- and mercury-resistant isolates was not demonstrable with metal resistance genes from plasmids of either gram-positive (pI258) or gram-negative (pDB7) origin. Cadmium resistance of all the marsh isolates tested resulted from reduced Cd2+ transport. On the other hand, three cadmium-resistant harbor isolates displayed considerable influx but no efflux of Cd2+. Hg-resistant strains detoxified mercury by transforming Hg2+ to volatile Hg0 via mercuric reductase.     

Stimulatory effect of phenylmercuric acetate and benzene on the growth of a broad spectrum mercury-resistant strain of Bacillus pasteurii

A broad spectrum mercury-resistant organism, Bacillus pasteurii DR₂, was isolated from the effluents of Durgapur Steel Plant, India. In the presence of phenylmercuric acetate or benzene the rate of glucose uptake and the level of some metabolic enzymes increased significantly. Inhibition of the glucose oxidation rate by these chemicals in lysozyme-treated cells indicated that these compounds facilitated the transport of glucose across the cell wall and thereby stimulated growth.     

Isolation and characterization of a mercury-resistant broad-host-range plasmid from Pseudomonas cepacia

Abstract The sequence of 1383 nucleotides of the DNA encoding 16S rDNA was determined for strains of human intestinal spirochaetes, comprising an unnamed isolate and " Brachyspira aalborgi " NCTC 11492. A phylogenetic tree was inferred from aligned sequence comparisons between the intestinal spirochaetes, representatives of the Spirochaetales and Escherichia coli . The type strain of Brachyspira aalborgi , though related to the Serpulina spp. at approx. 96.5% sequence similarity was distinct and separated from the unnamed human intestinal isolate, HIS Oman, N26. The latter formed a separated and novel lineage that bisected the Spirochaetales.     

Identification and characteristics of a novel Burkholderia strain with broad-spectrum antimicrobial activity

A Burkholderia strain isolated from soil is capable of inhibiting the growth of bacteria, plant-pathogenic fungi, pathogenic yeasts, and protozoa. Inhibition does not involve cell contact or the presence of living cells, suggesting that at least a substantial portion of the antimicrobial activity is due to the excretion of extracellular compounds.     

一株具有广谱抗菌活性炭样小单孢菌的全基因组序列测定

【目的】炭样小单孢菌JXNU-1是一株具有广谱抗菌活性的放线菌,研究揭示该菌的基因组序列信息。【方法】采用高通量测序技术对炭样小单孢菌JXNU-1的基因组DNA测序,利用SOAPdenovo软件组装,人工PCR修补基因组部分缺口,然后进行生物信息学分析。【结果】对炭样小单孢菌JXNU-1的全基因组序列进行了测定和注释,得到基因组精细图,相关序列已提交GenBank,获得登录号为JXSX00000000。【结论】研究为揭示炭样小单孢菌JXNU-1抗生素产生机制及其抗菌机理提供了基础数据,对进一步研发其抗生素具有重要的理论意义和巨大的应用价值。     

Hydrolytic potential of extracellular enzymes from a mutant strain of Fusarium oxysporum

Potential of extracellular enzymes of a mutant strain (NTG-19) of Fusarium oxysporum in hydrolysis of cellulosic materials was investigated. The enzyme preparation effectively hydrolyzed untreated as well as chemically pretreated sugarcane bagasse. About 95% hydrolysis could be achieved with sodium sulfite pretreated bagasse within 96 h. The enzymes exhibit appreciable stability during the course of hydrolysis.     

Heat sensitivity of mercuric ion and organomercurial degrading enzymes of aquatic,mercury-resistant bacteria

Activities of both Hg²⁺-reductase and organomercurial lyase of Hg-resistant aquatic bacteria were stable at 20°C for several days within whole cells. Organomercurial lyase activity degrading specifically thimersol, an organomercurial, was more stable than the corresponding enzyme activity degrading other organomercurials like phenylmercuric acetate (PMA) and methoxyethyl mercuric chloride (MEMC). Hg²⁺-reductases of Gram-negative bacteria in cell-free extract were more heat resistant than those of Gram-positive bacteria, except for those of two species of Bacillus, which were as heat resistant as those of the Gram-negative bacteria. Differences in the heat resistances of organomercurial lyases of two different broad-spectrum Hg-resistant bacteria indicate the presence of two enzyme systems for degrading thimersol, PMA and MEMC.     

Volatilization of mercury by an iron oxidation enzyme system in a highly mercury-resistant Acidithiobacillus ferrooxidans strain MON-1

A highly mercury-resistant strain Acidithiobacillus ferrooxidans MON-1, was isolated from a culture of a moderately mercury-resistant strain, A. ferrooxidans SUG 2-2 (previously described as Thiobacillus ferrooxidans SUG 2-2), by successive cultivation and isolation of the latter strain in a Fe2+ medium with increased amounts of Hg2+ from 6 microM to 20 microM. The original stain SUG 2-2 grew in a Fe2+ medium containing 6 microM Hg2+ with a lag time of 22 days, but could not grow in a Fe2+ medium containing 10 microM Hg2+. In contrast, strain MON-1 could grow in a Fe2+ medium containing 20 microM Hg2+ with a lag time of 2 days and the ability of strain MON-1 to grow rapidly in a Fe2+ medium containing 20 microM Hg2+ was maintained stably after the strain was cultured many times in a Fe2+ medium without Hg2+. A similar level of NADPH-dependent mercury reductase activity was observed in cell extracts from strains SUG 2-2 and MON-1. By contrast, the amounts of mercury volatilized for 3 h from the reaction mixture containing 7 microM Hg2+ using a Fe(2+)-dependent mercury volatilization enzyme system were 5.6 nmol for SUG 2-2 and 67.5 nmol for MON-1, respectively, indicating that a marked increase of Fe(2+)-dependent mercury volatilization activity conferred on strain MON-1 the ability to grow rapidly in a Fe2+ medium containing 20 microM Hg2+. Iron oxidizing activities, 2,3,5,6-tetramethyl-p-phenylenediamine (TMPD) oxidizing activities and cytochrome c oxidase activities of strains SUG 2-2 and MON-1 were 26.3 and 41.9 microl O2 uptake/mg/min, 15.6 and 25.0 microl O2 uptake/mg/min, and 2.1 and 6.1 mU/mg, respectively. These results indicate that among components of the iron oxidation enzyme system, especially cytochrome c oxidase activity, increased by the acquisition of further mercury resistance in strain MON-1. Mercury volatilized by the Fe(2+)-dependent mercury volatilization enzyme system of strain MON-1 was strongly inhibited by 1.0 mM sodium cyanide, but was not by 50 nM rotenone, 5 microM 2-n-heptyl-4-hydroxy-quinoline-N-oxide (HQNO), 0.5 microM antimycin A, or 0.5 microM myxothiazol, indicating that cytochrome c oxidase plays a crucial role in mercury volatilization of strain MON-1 in the presence of Fe2+.     

Naphthalene-utilizing and mercury-resistant bacteria isolated from an acidic environment

Soil samples were taken from areas of low pH (2.5–3.5) surrounding an outdoor coal storage pile. These samples were added to medium with naphthalene as the sole carbon source to enrich for organisms capable of degrading polycyclic aromatic hydrocarbons (PAH) at low pH. Five such bacterial strains were isolated. Sequencing of the 16S rDNA showed them to be members of the genera Clavibacter, Arthrobacter and Acidocella. These organisms were all capable of growth with naphthalene as a sole carbon source at low pH. The genes nahAc, nahAd, phnAc, nahH, xylE or GST, which are known to be associated with PAH degradation were not detected. Isolate 10, the Acidocella strain, tolerated high levels of mercury. PCR amplification and sequencing of genes from the mer operon from isolate 10 DNA suggested that mercury is transported into the bacterial cell and subsequently detoxified since the enzymes encoded by genes in this operon are involved in these processes.     

榕树根际土壤广谱拮抗菌株的筛选、鉴定及特性

于江西省吉安市内一株明万历年间植下的古榕树下,采集根际土样并使用23种指示菌通过管碟法和菌丝生长速率法对土壤内放线菌进行拮抗筛选,最终得到一株传代稳定的广谱拮抗菌株AHF-20.根据对菌株的形态观察、生理生化特性以及分子生物学鉴定,将该拮抗菌株鉴定为链霉菌,并对该菌株的抑菌活性物质进行了研究.结果表明:链霉菌AHF-20的发酵产物对23种测试指示菌全部具有拮抗效果,且抑菌能力稳定性较好,对温度、光照、紫外线、酸碱都有一定的耐受性,于121 ℃下加热20 min后依然存在抑菌活性.根据活性物质的极性使用正丁醇萃取发酵产物,获得的正丁醇粗提物稀释至1 μg·mL^-1后,对大肠杆菌仍有抑制效果,可见具有较好的生防利用潜力和开发成新型微生物药物的可能性.     

Lactobacillus coryniformis subsp. coryniformis strain Si3 produces a broad-spectrum proteinaceous antifungal compound

The antifungal activity spectrum of Lactobacillus coryniformis subsp. coryniformis strain Si3 was investigated. The strain had strong inhibitory activity in dual-culture agar plate assays against the molds Aspergillus fumigatus, A. nidulans, Penicillium roqueforti, Mucor hiemalis, Talaromyces flavus, Fusarium poae, F. graminearum, F. culmorum, and F. sporotrichoides. A weaker activity was observed against the yeasts Debaryomyces hansenii, Kluyveromyces marxianus, and Saccharomyces cerevisiae. The yeasts Rhodotorula glutinis, Sporobolomyces roseus, and Pichia anomala were not inhibited. In liquid culture the antifungal activity paralleled growth, with maximum mold inhibition early in the stationary growth phase, but with a rapid decline in antifungal activity after 48 h. The addition of ethanol to the growth medium prevented the decline and gave an increased antifungal activity. The activity was stable during heat treatment and was retained even after autoclaving at 121 degrees C for 15 min. Maximum activity was observed at pH values of between 3. 0 and 4.5, but it decreased rapidly when pH was adjusted to a level between 4.5 and 6.0 and was lost at higher pH values. The antifungal activity was fully regained after readjustment of the pH to the initial value (pH 3.6). The activity was irreversibly lost after treatment with proteolytic enzymes (proteinase K, trypsin, and pepsin). The antifungal activity was partially purified using ion-exchange chromatography and (NH(4))(2)SO(4) precipitation, followed by gel filtration chromatography. The active compound(s) was estimated to have a molecular mass of approximately 3 kDa. This is the first report of the production of a proteinaceous antifungal compound(s) from L. coryniformis subsp. coryniformis.