溴氨酸降解菌株的分离和特性

从化工厂污泥中中分离到4个对蒽醌染料中间体溴氨酸有显降解和脱色作用的菌株。经鉴定,4株菌均为假单胞菌属（Pseudomonas sp.）。脱色效果最好的N1菌株能以溴酸为唯一碳源生长,其脱色效果受温度和pH影响较大,最佳生长条件是30℃,pH7.2。     

高效芘降解菌N12的分离鉴定与降解特性

以芘为目标降解物,利用选择性富集培养方法,从沈抚灌区污染土壤中分离到一株高效芘降解菌N12,经生理生化试验和16S rDNA测序分析,该菌被鉴定为分枝杆菌属（Mycobacterium sp.）.菌株N12能以菲、苊、芴和芘为唯一碳源和能源生长,不能以蒽、萘和苯并芘为唯一碳源和能源生长.在菲和芘共同存在的情况下菌株N12可降解苯并芘,9 d内对苯并芘降解率可达79.0%.摇瓶降解试验表明,菌株N12可在7 d内将100 mg·L^-1的芘降解94.4%,14 d内将其完全降解;可将600 mg·L^-1的芘在7 d内降解56.1%,14 d内降解95.5%.添加葡萄糖可促进N12对芘的降解.菌株N12是一株优良的多环芳烃降解菌,可作为多环芳烃污染土壤生物修复的菌种资源.     

一株高效降解芘的细菌分离、鉴定及其降解效果

摘要：【目的】获得高效降解高分子量多环芳烃的细菌,并研究其对多环芳烃的降解能力。【方法】利用富集培养和芘升华平板方法,从焦化厂污染土壤中分离多环芳烃降解细菌,对分离菌株通过形态特征、16S rRNA基因和gyrb基因序列相似性分析进行鉴定,并研究该菌对高分子量多环芳烃（HMW-PAHs）的降解效果。【结果】筛选到一株能以芘、苯并蒽、屈、苯并芘、茚并芘、苯并苝、荧恩为碳源和能源生长并降解这些底物的菌株HBS1,该菌株的16S rRNA基因和gyrb基因序列与Gordonia amicalis的相应基因的相似     

Enterobacter spp.：引起“桑枯萎”病的新证据

从浙江省杭州地区＂桑枯萎＂病树上分离获得36株病原细菌,通过对6株代表菌的常规细菌学、电子显微镜观察、致病性及Koch氏假说测定、Biolog鉴定、脂肪酸分析、生理生化、ERIC-PCR（enterobacterial repetitive intergenic consensus-PCR）分析、16S rRNA序列分析,同时与肠杆菌属（Enterobacter）中与植物有关的7个模式种菌株和其他3株参考菌株的比较,确认＂桑枯萎＂病为肠杆菌属中1个以上的新种（Enterobacter spp.）所引起.＂桑枯萎＂病是一种国内外尚未报道的桑树新病害,是Enterobacter spp.引起植物病害的又一新证据.该研究结果不但对桑树病害的治理具有实际意义,而且对深入研究Enterobacter中的人体条件致病菌及环保菌具有重要的学术价值。     

中国白块菌——攀枝花块菌子囊果内可培养细菌的多样性研究

对新近发现的块菌属一新种——攀枝花白块菌（Tuber panzhihuanense）子囊果中可培养细菌的多样性进行了研究。采用胰蛋白大豆培养基（TSA）对菌株进行分离。用毛细管电泳（HPCE）对所有获得的菌株的16S rDNA V3高变区进行筛选获得不同条带大小的菌株,对筛选出的菌株的16S rDNA进行测序,并进行细菌多样性分析和研究。结果显示,攀枝花块菌子囊果内可培养细菌在数量及种类上都表现出很高的多样性,所有细菌分属于5个门的11个属和20个种。在所分离到的变形菌门的细菌中,数量最多的菌株（4968%）属于γ Proteobacteria,其中假单胞菌属的Pseudomonas lurida为优势类群;其次为α Proteobacteria,占3742%,其中以固氮菌 Bradyrhizobium japonicum和Phyllobacterium spp.为优势类群。其余的菌株属于放线菌门（Actinobacteria） （322%）和厚壁菌门（Firmicutes） （774%）,厚壁菌门中以芽孢杆菌属（Bacillus）为代表菌群。酸杆菌门中的Terriglobus roseus（194%）首次从块菌中分离获得。     

3株多环芳烃高效降解菌株的分离鉴定及降解特性

筛选分离降解多环芳烃(PAHs)的优势菌种对开展多环芳烃污染生态系统修复具有重要的现实意义。本研究以焦化厂周围受多环芳烃污染的土壤为菌源,经过富集培养驯化和平板分离,获得11株能降解多环芳烃的菌株。通过形态观察、生理生化特征及16S rRNA序列比对对菌株进行鉴定,筛选出3株PAHs高效降解菌,分别命名为DJ-3、DJ-8、DJ-10。经16S rRNA序列分析鉴定,DJ-3为假单胞菌属、DJ-8为克雷伯氏菌属、DJ-10为芽孢杆菌属。对菌株降解能力的研究表明,3株菌(DJ-3、DJ-8、DJ-10)培养7 d后对混合多环芳烃中菲(200 mg·L^-1)、芘(200 mg·L^-1)和萘(160 mg·L^-1)的降解率分别为48.9%～65.9%、38.9%～43.1%和57.6%～64.9%。3株菌对多环芳烃混合样品(1200 mg·L^-1)的降解率分别为49.1%、44.5%、53.9%,远高于其他8株筛选菌,为PAHs高效降解菌株。3种菌株两两之间和三者组合均无拮抗关系。研究结果将为构建高效的多环芳烃降解菌群、提高多环芳烃原位污染土壤的生物修复效果奠定基础。     

一株高产黑色素香灰菌菌株的鉴定、筛选及培养条件的优化

为筛选一株产黑色素能力强的菌株并优化其培养条件。通过ITS测序鉴定11株供试菌株,以菌丝生长速度、平板L值等指标筛选出一株产黑能力强的香灰菌,并对其生长所需碳源、氮源、pH等培养条件进行优化。研究表明,11株供试菌株均为香灰菌（Hypoxylon sp.）,其中Hp.sp0006菌丝生长速度较快、菌球大且均匀、L值最低,并且发酵液黑色素含量最高。该菌株最优培养条件是,以葡萄糖为碳源、牛肉浸膏为氮源、碳氮比20∶1并添加10 mg维生素B₁,黑色素含量可达（1.21±0.17）g/L。香灰菌Hp.sp0006是一株产黑色素较高的菌株,优化后的培养基更有利于黑色素的合成,为香灰菌黑色素的开发利用奠定基础。     

联苯降解细菌的分离及其降解质粒某些特性的研究

:通过选择性富集培养 ,从芳烃污染的土壤中分离得到 16株以联苯作唯一碳源生长的细菌。初步鉴定 ,3株均为假单孢菌属(Psedomonas) 。都含有大小 2个质粒。质粒不稳定 ,易丢失。经苯甲酸钠和口丫啶橙的消除实验 ,结果表明 ,随着质粒丢失 ,菌株利用Bp生长的能力也丧失。酶活性分析表明 ,菌株只有邻苯二酚 2 ,3—氧化酶活性 ,没有邻苯二酚1 ,2—氧化酶活性。菌株对联苯的降解率 :bp2 菌为 93%、bp2 3菌为 81%、bp2 4 菌为 99%。降解过程中产生λmax331nm和λmax4 34nm2种中间代谢物。     

自然环境分离磺胺甲噁唑抗性细菌抗药性及其抗性基因分析

为了解自然环境源细菌对磺胺类抗生素的抗性特征,采用纯培养物分离技术从淮河底泥中筛选磺胺甲噁唑(SMZ)抗性细菌,测定其抗性水平,PCR扩增进一步分析其抗性基因(sul)和一类整合子(intl)。结果从该底泥样品中分离出4株SMZ抗性细菌,经鉴定分别为Arthrobacter spp.Y1、Bacillus spp.Y2、Acinetobacter spp.Y4和Bacillus spp.H。菌株对SMZ的抗性水平从低到高依次为Y4 (0.5)、Y1 (5)、H (10)和Y2 (10 mg/mL)。4个SMZ抗性菌株均携带sul1基因,但均不含sul3和sulA基因,其中菌株H同时携带sul2基因。菌株Y2和Y4含有一类整合子,但是菌株Y1和H不含该整合子。本研究有助于加深对自然环境源SMZ抗性细菌抗性特征及其潜在风险的认知。     

广陈皮外源真菌的组成及产毒真菌分析

【背景】广陈皮为药食同源中药材,在高温、高湿且贮存不当的条件下容易发霉,从而产生毒素,严重威胁陈皮的质量安全。【目的】分析广陈皮表面外源真菌的组成及其产生毒素的真菌。【方法】采用平板稀释法分离广陈皮表面外源真菌,利用分生孢子形态特征及DNA序列分析进行真菌鉴定,采用高效液相色谱-三重串联四极杆质谱联用技术对青霉属和曲霉属进行产毒检测。【结果】从广陈皮表面分离外源真菌共132株,鉴定为子囊菌亚门（Ascomycota,98.48%）和毛霉菌亚门（Mucoromycota,1.52%）,包括散囊菌纲（Eurotiomycetes,95.45%）、座囊菌纲（Dothideomycetes,3.03%）和毛霉纲（Mucoromycetes,1.52%）。分离活动曲霉属（Aspergillus spp.）菌株共77株,为广陈皮药材外源真菌的优势菌,青霉属（Penicillium spp.）次之。毒素检测筛选出1株产毒真菌,鉴定为黄曲霉（Aspergillus flavus） JXCP1-3。该菌株产生黄曲霉毒素B₁ （aflatoxin B₁,AFB<...     

Investigation of alkane biodegradation using the microtiter plate method and correlation between biofilm formation, biosurfactant production and crude oil biodegradation

Among 25 crude oil-degrading bacteria isolated from a marine environment, four strains, which grew well on crude oil, were selected for more study. All the four isolated had maximum growth on 2.5% of crude oil and strain BC (Pseudomonas) could remove crude oil by 83%. The drop collapse method and microtiter assay show that this strain produces more biosurfactant, and its biofilm formation is higher compared to other strains. Bacterial adhesions to crude oil for strains CS-2 (Pseudomonas), BC, PG-5 (Rhodococcus) and H (Bacillus) were 30%, 46%, 10% and 1%, respectively. Therefore, strain H with a low production of biosurfactant and biofilm formation had showed the least growth on these compounds. PCR analysis of these four strains showed that all isolates had alk-B genes from group (III) alkane hydroxylase. All isolate strains could utilize cyclohexan, octane, hexadecane, octadecan and diesel fuel oil; however, the microtiter plate assay showed that strain BC had more growth, respiration and biofilm formation on octadecan.     

Isolation and Characterization of Biosurfactant-Producing Bacteria from Oil-Contaminated Soil

Two biosurfactant-producing Pseudomonas aeruginosa strains (KISR C1 and KISR B1) were isolated from Kuwaiti oil-contaminated soil, which resulted from the Gulf War. The optimum environmental conditions that supported the growth and surfactant production of both isolates were examined. The two isolates differed in their biosurfactant-stimu-lating carbon source, nitrogen concentration, and the pH of the medium. C-1 isolate produced two types of rhamnolipids with a final concentration of 98.4?g/l after spiking the nitrogen-limited medium with 10?mg/ml olive oil. The other isolate (B-1) produced only one type of rhamnolipid (5.9?g/l) after spiking the medium with crude oil. The biosurfactant produced by this strain was found to be very effective in the emulsifica-tion of crude oil. The result suggests that this isolate can potentially be used to enhance bioremediation of oil-contamination and enhanced oil recovery.     

Biodegradation of Crude Oil by Thermophilic Bacteria Isolated from a Volcano Island

One-hundred and fifty different thermophilic bacteria isolated from a volcanic island were screened for detection of an alkane hydroxylase gene using degenerated primers developed to amplify genes related to the Pseudomonas putida and Pseudomonas oleovorans alkane hydroxylases. Ten isolates carrying the alkJ gene were further characterized by 16s rDNA gene sequencing. Nine out of ten isolates were phylogenetically affiliated with Geobacillus species and one isolate with Bacillus species. These isolates were able to grow in liquid cultures with crude oil as the sole carbon source and were found to degrade long chain crude oil alkanes in a range between 46.64% and 87.68%. Results indicated that indigenous thermophilic hydrocarbon degraders of Bacillus and Geobacillus species are of special significance as they could be efficiently used for bioremediation of oil-polluted soil and composting processes.     

Hydrocarbon degradation in relation to cell-surface hydrophobicity among bacterial hydrocarbon degraders from petroleum-contaminated Kuwait desert environment

Forty six bacterial isolates able to grow on crude oil were isolated from various hydrocarbon-contaminated sites in Kuwait. The extent of crude oil degradation varied over a wide range (1–87%) among the isolates. Isolates were predominantly Gram-positive bacteria (79% of total isolates) belonging to the genera Bacillus (93%) and Paenibacillus (7%). Among the few Gram-negative isolates were from the genera Acinetobacter, Alcaligenes, Klebsiella, Burkholderia, Pseudomonas, and Williamsia. Analyses of their cell-surface hydrophobicity (CSH) by various methods equally showed a wide variation among the isolates. About 74% of isolates that degraded significant amounts of crude oil (>40% degradation) possessed high level of CSH, while 58% of all the isolates exhibited high levels of CSH. Statistical analyses showed significantly high correlation between the ability to degrade crude oil and CSH. The ability of the isolates to bind to polystyrene and salt-aggregation test as measures of CSH were more strongly correlated with hydrocarbon-degrading ability than adherence to hydrocarbons.     

Influence of crude oil on changes of bacterial communities in Arctic sea-ice

The danger of a petroleum hydrocarbon spillage in the polar, ice-covered regions is increasing due to oil exploration in Arctic offshore areas and a growing interest in using the Northern Sea Route (NSR) as an alternative transportation route for Arctic oil and gas. However, little is known about the potential impact of accidental oil spills on this environment. We investigated the impact of crude oil on microbial community composition in six different Arctic sea-ice samples incubated with crude oil at 1 degrees C in microcosms for one year. Alterations in the composition of bacterial communities were analyzed with the culture-independent molecular methods DGGE (denaturing gradient gel electrophoresis) and FISH (fluorescence in situ hybridization). DGGE, FISH and cultivation methods revealed a strong shift in community composition toward the gamma-proteobacteria in sea-ice and melt pool samples incubated with crude oil. Marinobacter spp., Shewanella spp. and Pseudomonas spp. were the predominant phylotypes in the oil-treated microcosms. The ability of indigenous sea-ice bacteria to degrade hydrocarbons at low temperature (1 degrees C) was tested using four representative strains cultivated from sea-ice enriched with crude oil. [14C]Hexadecane was degraded by the sea-ice isolates at 20-50% capacity of the mesophilic type strain Marinobacter hydrocarbonoclasticus, a known hydrocarbon degrader, incubated at 22 degrees C.     

Mycoremediation of crude oil contaminated soil by specific fungi isolated from Dhahran in Saudi Arabia

Crude oil biodegrading microorganism considers the key role for environmental preserving. In this investigation, crude oil biodegrading fungal strains have been isolated in polluted soil of crude-oil at khurais oil ground in Kingdom of Saudi Arabia. Among of 22 fungal isolates, only three isolates reflected potential capability for oil degradation. These isolates were identified and submitted to GenBank as (A1) Aspergillus polyporicola (MT448790), (A2) Aspergillus spelaeus (MT448791) and (A3) Aspergillus niger (MT459302) through internal-transcribed spacer-regions (ITS1&ITS2) for sequencing in molecular marker. Comparing with controls, strain (A1) Aspergillus niger was superior for biodegradation ability (58%) comparing with Aspergillus polyporicola and Aspergillus spelaeus degrading were showed 47 and 51% respectively. Employed CO₂ evolution as indicator for petroleum oil biodegradation by the fungal isolates reflected that, Aspergillus niger emission highest CO2 (28.6%) comparing with Aspergillus spelaeus and Aspergillus polyporicola which showed 13% and 12.4% respectively. capability of Aspergillus sp. to tolerate and adapted oil pollutants with successful growth rate on them, indicated that it can be employed as mycoremediation agent for recovering restoring ecosystem when contaminated by crude oil.     

Biosurfactant production by Mucor circinelloides: Environmental applications and surface‐active properties

Biosurfactants are structurally a diverse group of surface‐active molecules widely used for various purposes in industry. In this study, among 120 fungal isolates, M‐06 was selected as a superior biosurfactant producer, based on different standard methods, and was identified as Mucor circinelloides on the basis of its nucleotide sequence of the internal transcribed spacer (ITS) gene. M. circinelloides reduced the surface tension to 26 mN/m and its EI₂₄ index was determined to be 66.6%. The produced biosurfactant exhibited a high degree of stability at a high temperature (121°C), salinity (40 g/L), and acidic pH (2–8). The fermentation broth's ability to recover oil from contaminated sand was 2 and 1.8 times higher than those of water and Tween 80, respectively. The ability of biosurfactant to emulsify crude oil in the sea and fresh water was 64.9 and 48% respectively. This strain could remove 87.6% of crude oil in the Minimal Salt Medium (MSM) crude oil as the sole carbon source. The results from a primary chemical characterization of crude biosurfactant suggest that it is of a glycolipid nature. The strain and its biosurfactant could be used as a potent candidate in bioremediation of oil‐contaminated water, soil, and for oil recovery processes.     

Effect of biosurfactant and fertilizer on biodegradation of crude oil by marine isolates of Bacillus megaterium, Corynebacterium kutscheri and Pseudomonas aeruginosa

This study was conducted to investigate the effects of fertilizers and biosurfactants on biodegradation of crude oil by three marine bacterial isolates; Bacillus megaterium, Corynebacterium kutscheri and Pseudomonas aeruginosa. Five sets of experiments were carried out in shake flask and microcosm conditions with crude oil as follows: Set 1-only bacterial cells added (no fertilizer and biosurfactant), Set 2-with additional fertilizer only, Set 3-with additional biosurfactant only, Set 4-with added biosurfactant + fertilizer, Set 5-with no bacterial cells added (control), all the above experimental sets were incubated for 168 h. The biosurfactant + fertilizer added Set 4, resulted in maximum crude oil degradation within shake flask and microcosm conditions. Among the three bacterial isolates, P. aeruginosa and biosurfactant produced by this strain resulted in maximum crude oil degradation compared to the other two bacterial strains investigated. Interestingly, when biosurfactant and bacterial cells were used (Set 3), significant oil biodegradation activity occurred and the difference between this treatment and that in Set 4 with added fertilizer + biosurfactant were only 4-5% higher degradation level in shake flask and 3.2-7% in microcosm experiments for all three bacterial strains used. It is concluded that, biosurfactants alone capable of promoting biodegradation to a large extent without added fertilizers, which will reduce the cost of bioremediation process and minimizes the dilution or wash away problems encountered when water soluble fertilizers used during bioremediation of aquatic environments.     

Crude oil utilization by fungi.

Sixty fungal isolates, 34 obtained by a static enrichment technique from soils of northern Canadian oil-producing areas and 26 from culture collections, were screened for their ability to grow on n-tetradecane, toluene, naphthalene, and seven crude oils of varying composition. Forty cultures, including 28 soil isolates, were capable of growth on one or more crude oils. The genera most frequently isolated from soils were those producing abundant small condida, e.g. Penicillium and Verticillium spp. Oil-degrading strains of Beauveria bassiana, Mortieriella sp., Phoma sp., Scolecobasidium obovatum, and Tolypocladium inflatum were also isolated. Qualitative and quantitative differences were noted among the capacities of different crude oils to sustain the growth of individual fungal isolates. Data are presented which show that ability to grow on a pure n-alkane is not a good indicator of ability to grow on crude oil. Degradation of Rainbow Lake crude oil by individual isolates was demonstrated by gravimetric and gas-chromatographic techniques. The problems involved in determining the response and the potential of fungi to degrade oil spilled in the environment are discussed.     

Enhanced crude oil biodegradability of <Emphasis Type="Italic">Pseudomonas aeruginosa</Emphasis> ZJU after preservation in crude oil-containing medium

This study investigated the enhanced crude oil biodegradability of Pseudomonas aeruginosa ZJU, a strain isolated from the Shengli oil field (Shandong Province, China), after preservation in a crude oil-containing medium. This strain previously could not emulsify crude oil during preservation, but after switching to a subculture in a glycerol medium for passages, it expressed increased biodegradation of crude oil within the first six passages and this biodegradation sharply decreased after the seventh passage. It is noticed that about 70% of crude oil was degraded by Pseudomonas aeruginosa ZJU in the third passage while this biodegradability was less than 19% in the seventh passage. Similar to the trend on biodegradation of crude oil, rhamnolipid production increased during the first six passages and later sharply decreased. Thus, it seems that biodegradability was proportionally related to the rhamnolipid productivity in each passage in glycerol medium. Interestingly, both rhamnolipid production and crude oil biodegradation were maintained if this strain was continuously preserved in crude oil and could be retrieved if this strain was then re-preserved in crude oil-containing medium for seven days after the significant decline in these two characteristics previously observed in the seventh passage.