U(Ⅵ)在芽孢杆菌Bacillus sp.dwc-2上的矿化动力学研究

微生物诱导的U(Ⅵ)生物矿化会影响铀在环境中的化学形态和迁移行为,但目前对于生长和繁殖阶段的微生物诱导U(Ⅵ)矿化的动力学行为研究不多,相关的机制也不明确。本文从某拟用作极低放射性废物处置场场所的土壤中分离出1株芽孢杆菌Bacillus sp.dwc-2,考察了pH值、甘油磷酸钠(SGP)、U(Ⅵ)初始浓度等因素对Bacillus sp.dwc-2在生长繁殖过程中诱导U(Ⅵ)矿化动力学行为的影响,并对其矿化机制进行了探讨。结果表明,Bacillus sp.dwc-2可诱导U(Ⅵ)形成钠铀云母(NaUO_(2)PO_(4)·3H_(2)O)的晶体矿物,该过程作为一种酶促反应,受pH值、SGP浓度、U(Ⅵ)初始浓度等因素的显著影响;当U(Ⅵ)初始浓度从50 mg/L增加至150 mg/L时,刺激了处于生长迟滞期至对数期(培养0~12 h)菌体磷酸酶活性的表达和磷酸盐的代谢,使其诱导U(Ⅵ)的矿化行为发生在生长对数期(培养12 h);SGP浓度的增加促进了磷酸酶的催化反应速率,进而促进了U(Ⅵ)的矿化,当SGP的浓度从25 mmol/L增加到125 mmol/L时,Bacillus sp.dwc-2诱导U(Ⅵ)的矿化时间从其生长稳定期(培养24 h)提前至生长对数期(培养12 h);中性和碱性条件下,磷酸酶活性在生长迟滞期至对数期(培养0~12 h)快速增加,从而促进了磷酸盐的消耗和U(Ⅵ)的矿化,特别是在碱性条件下,沉积物在生长对数期(培养8 h)时即转化为明显的晶体矿物。

厌氧条件下芽孢杆菌Bacillus sp.dwc-2对模拟地下水中U(VI)的吸附行为研究

本文在厌氧条件下,研究了西南地区土壤中一种典型微生物芽孢杆菌 Bacillus sp .dwc-2对模拟地下水U(Ⅵ)的吸附行为,重点考察了时间、pH、NaHCO3、温度、阴离子、腐殖酸以及富里酸对吸附的影响,并利用SEM、EDS、FT-IR和XRD对样品进行了表征。结果表明:在pH 7.0、[NaHCO3]=5 mmol·L^-1 和 T =30 ℃条件下,芽孢杆菌对U(Ⅵ)有最大的吸附率。初始pH值升高及阴离子浓度增大会抑制芽孢杆菌对U(Ⅵ)的吸附;随着U(Ⅵ)初始浓度的增加,芽孢杆菌对U(Ⅵ)的吸附率呈先增加后降低的趋势;腐殖酸和富里酸则会抑制芽孢杆菌吸附U(Ⅵ)。吸附均在120 h达到平衡,吸附过程均符合准二级动力学模型,说明吸附以化学吸附为主。Langmuir和Freundlich模型拟合结果显示,芽孢杆菌吸附U(Ⅵ)为单分子层吸附。上述结果可为真实环境中微生物吸附U(Ⅵ)提供基础数据和参考。

海洋细菌Bacillus sp.H-TP2岩藻多糖酶的生产和酶学性质

研究了海洋细菌Bacillussp H TP2液态发酵生产岩藻多糖酶的条件 ,并对酶学性质进行了初步探讨。主要包括氮源、碳源、起始pH、温度、盐浓度和添加物等对产酶的影响。培养基组成为 :岩藻多糖 3g/L、尿素 5g/L、NH4 NO32g/L、CaCl2 ·2H2 O 0 0 5g/L、MgSO4 ·7H2 O 2g/L、Na2 HPO40 5g/L、葡萄糖 0 4g/L、蛋白胨 4g/L。菌种在 2 0℃ ,起始pH 7 0 ,1 2 5倍海水盐度下 ,培养 2 4h ,酶活力可以达到 1 2 9IU/mL。另外 ,该酶的最适反应温度为 5 0℃ ,最适反应pH为 6 5。

Characterization of an extracellular polysaccharide produced by Bacillus sp.RL-2

A strain secreting a strongly acidic polysaccharide flocculating agent was isolated from activated sludge, and identified as Bacillus brevis. The bioflocculant was produced by RL-2 during the late logarithmic growth in the batch culture and was recovered from supernatant by ethanol precipitation. The bioflocculant is thermo-stable as its activity remains stable after heated at 100 °C for 45 min. Its flocculating activity with kaolin suspensions was stimulated by the addition of Ca2+, Al3+ and Cu2+. The flocculant consists of glucose, mannose, and galacturonic acid. Its average molecular mass was estimated to be approximately 2.86×105 by the method of viscosity. The flocculant aggregates various inorganic and organic compounds in solution.

小麦丰收菌(Bacillus sp.W_(2—6))对小麦生长前期的生理效应研究

小麦丰收菌(Bacillus sp.W_(2-6)能提高麦株鲜重2.23％～19.3％、干重1.03％～14.31％、叶绿素含量3.61％～38.91％、净光合速率7.26％～11.53％、CAT酶活性22.23％～79.34％。SOD酶活性在三叶期时低于对照,而拔节和孕穗期均比对照高。过氧化物酶同工酶图谱无明显差异。该菌对小麦有较强的促生作用,并有随生育进程而提高的趋势。该菌不会引起小麦的遗传变异。

蛋白酶高产菌株的筛选鉴定与酶学特性研究

以酪蛋白水解圈为筛选标记,在以酪蛋白为唯一氮源的平板上,从土壤中分离筛选到3株高产蛋白酶的菌株,经形态学鉴定和16S rRNA分析,将其分别鉴定为Bacillus sp.G1、Bacillus sp.G2、Stenotrophomonas sp.V1。将这3株菌株的发酵液通过硫酸铵分级沉淀初步纯化后,其比酶活分别为22.21、19.10和16.03 U/mg。菌株Bacillus sp.G1和Bacillus sp.G2所产蛋白酶的最适反应温度和最适反应pH值均为40℃和7.0;菌株Stenotrophomonas sp.V1所产蛋白酶的最适反应温度为70℃,最适酶反应pH值为7.5。

两步固态发酵法酿造功能性豆豉

运用分离自云南传统发酵豆豉的Bacillus subtilis SP-8-5与Lactobacillus plantarum YM-5-2菌株对大豆进行两步固态混合发酵。首先,将菌株B.subtilis SP-8-5接种至经室温浸泡10 h(20℃,质量比为1∶3),110℃(20min)蒸煮处理并冷却至30℃的大豆中,于26℃进行初步发酵42 h;随后再接种L.plantarum YM-5-2,并于30℃发酵2 d,最后置于4℃进行后发酵。经两步固态混合发酵处理后,得到一种纤溶活性较强,生产周期短,保质期相对较长,风味独特且易于被大众接受的新型功能性发酵豆豉。当后发酵时间为21 d时,样品豆豉中B.subtilisSP-8-5活菌数为(5.88±0.53)×108 CFU/g,而L.plantarum YM-5-2活菌数则高达(3.50±0.35)×1011 CFU/g,此时检测豆豉纤溶酶的纤溶圈直径高达(2.99±0.06)cm(37℃,静置培养48 h)。

Isolation of Cr(Ⅵ) reducing bacteria from industrial effuents and their potential use in bioremediation of chromium containing wastewater

The present study was aimed to assess the ability of Bacillus sp.JDM-2-1 and Staphylococcus capitis to reduce hexavalent chromium into its trivalent form.Bacillus sp.JDM-2-1 could tolerate Cr（Ⅵ）（4800 μg/mL） and S.capitis could tolerate Cr（Ⅵ）（2800 μg/mL）.Both organisms were able to resist Cd^2＋（50 μg/mL）,Cu^2＋（200 μg/mL）,Pb^2＋（800 μg/mL）,Hg^2＋（50 μg/mL） and Ni2＋（4000 μg/mL）.S.capitis resisted Zn^2＋ at 700 μg/mL while Bacillus sp.JDM-2-1 only showed resistance up to 50 μg/mL.Bacillus sp.JDM-2-1 and S.capitis showed optimum growth at pH 6 and 7,respectively,while both bacteria showed optimum growth at 37°C.Bacillus sp.JDM-2-1 and S.capitis could reduce 85% and 81% of hexavalent chromium from the medium after 96 h and were also capable of reducing hexavalent chromium 86% and 89%,respectively,from the industrial effuents after 144 h.Cell free extracts of Bacillus sp.JDM-2-1 and S.capitis showed reduction of 83% and 70% at concentration of 10 μg Cr（Ⅵ）/mL,respectively.The presence of an induced protein having molecular weight around 25 kDa in the presence of chromium points out a possible role of this protein in chromium reduction.The bacterial isolates can be exploited for the bioremediation of hexavalent chromium containing wastes,since they seem to have a potential to reduce the toxic hexavalent form to its nontoxic trivalent form.

菌株Arthrobacter sp.CN2降解对硝基苯酚的特性与动力学

为研究对硝基苯酚降解菌Arthrobacter sp.CN2在实际生产中的应用潜力,本文分别分析了p H、盐浓度和额外添加碳源对降解效率的影响,同时对降解的动力学方程进行拟合分析.菌株CN2在p H 7.0~8.0,Na Cl浓度60 g·L-1之间能够高效降解对硝基苯酚,72 h内对50 mg·L-1对硝基苯酚的降解率均大于90%.同时发现适量添加葡萄糖(0.5%)可显著促进CN2降解对硝基苯酚,与不添加葡萄糖条件下相比,达到90%降解率所需时间缩短了16 h.当对硝基苯酚浓度低于300 mg·L-1时,菌株CN2对对硝基苯酚的降解符合一级动力学方程,降解速率常数在0.021 7~0.025 0之间.在生物反应器中应用菌株CN2模拟处理工业废水,3 L含对硝基苯酚废水(100 mg·L-1)在72h的降解率大于90%.研究表明,菌株Arthrobacter sp.CN2能够高效地降解对硝基苯酚,对于环境有良好适应能力,具有良好的应用前景.

嗜碱Bacillus sp.N16-5不同碳源条件下比较蛋白质组分析

为了解碳水化合物对嗜碱微生物代谢途径的影响,用蛋白质组学方法比较分析了不同碳源条件下培养的嗜碱菌的胞浆蛋白质变化,试图找到差异表达的蛋白.分离自内蒙古乌杜淖尔碱湖的嗜碱Bacillussp.N16-5,在含有5种不同碳源(葡萄糖、甘露糖、半乳糖、阿拉伯糖和木糖)的培养基中培养.比较蛋白质组学分析鉴定了61个差异表达蛋白,它们主要参与碳水化合物代谢、氨基酸转运和代谢、能量的产生和贮存.结果表明,不同碳水化合物条件下参与中央代谢途径酶的丰度发生了很大的变化,尤其是碳代谢调控蛋白A(CcpA)均被上调.同时发现,在CcpA参与调控的碳代谢抑制现象中戊糖表现出比己糖更强的效应.上述结果为进一步理解嗜碱微生物碳水化合物代谢奠定了基础.

Comparative proteome analysis of alkaliphilic Bacillus sp.N16-5 grown on different carbon sources

To determine the impact of carbohydrates on the metabolic pathway in alkaliphiles, proteomes were obtained from cultures containing different carbohydrates and were resolved on two-dimensional gel electrophoresis (2-DE). The proteomes were compared to determine differentially expressed proteins. A novel alkaliphilic bacterium (alkaliphilic Bacillus sp. N16-5 isolated from Wudunur Soda Lake, China) was isolated in media with five different carbon sources (glucose, mannose, galactose, arabinose, and xylose). Comparative proteome analysis identified 61 differentially expressed proteins, which were mainly involved in carbohydrate metabolism, amino acid transport, and metabolism, as well as energy production and conversion. The comparison was based on the draft genome sequence of strain N16-5. The abundance of enzymes involved in central metabolism was significantly changed when exposed to various carbohydrates. Notably, catabolite control protein A (CcpA) was up-regulated under all carbon sources compared with glucose. In addition, pentose exhibited a stronger effect than hexose in CcpA-mediated carbon catabolite repression. These results provided a fundamental understanding of carbohydrate metabolism in alkaliphiles.

两种纤溶酶的酶学性质比较与溶栓机理分析

对芽孢杆菌(Bacillus sp.nov.SK006)发酵产生的两种纤溶酶(SPFE-1和SPFE-2)的酶学性质和溶栓机理进行分析比较,并研究其酶促反应动力学参数。试验结果表明:SPFE-1和SPFE-2具有较好的耐热性和pH稳定性;Zn2+能促进SPFE-1的纤溶活力,但强烈抑制SPFE-2;PMSF对SPFE-1h具有强烈的抑制作用;SPFE-1和SPFE-2都可直接降解纤维蛋白,也可激活纤溶酶原,从而间接降解纤维蛋白;SPFE-1最先降解纤维蛋白原的β链,然后是α链,很难降解γ链;SPFE-2顺次降解纤维蛋白原的α、β和γ链;SPFE-1和SPFE-2有较强的酰胺水解活性,最适底物为N-Succ-Ala-Ala-Pro-Phe-pNA;其作用于最佳底物的特征常数:Km=0.6/0.51mmol/L;kcat=712/154.25/s;kcat/Km=1.19×106/3.02×105L/(mol·s)。

降解1,3-二甲基-2-咪唑烷酮细菌的分离及功能评价

【背景】1,3-二甲基-2-咪唑烷酮(1,3-Dimethyl-2-Imidazolidinone,DMI)作为一种强极性非质子溶剂,在生产和应用过程的环境中有稳定残留问题,存在安全隐患。【目的】分离筛选具有降解DMI能力的微生物菌株,为清除环境中残留的DMI提供优良的微生物菌种资源。【方法】从DMI生产区域土壤采集样品分离DMI抗性微生物,采用形态学及分子生物学鉴定确定其分类地位,并对DMI降解能力进行测定。【结果】分离到最高能够耐受5%(体积分数)DMI的微生物菌株,形态学及分子生物学鉴定初步表明获得的菌株DT-1和DT-2为贝莱斯芽孢杆菌(Bacillus velezensis);全细胞及细胞提取液均具有降解DMI的能力;其中菌株DT-1及其细胞提取液对1%(体积分数)DMI的降解率分别达到48%和68%。【结论】从DMI生产区域土壤中分离到具有DMI降解能力的芽孢杆菌,不但可为DMI污染的微生物治理提供优良微生物资源,而且扩展了人们对芽孢杆菌生物学功能的认识。

纤维素降解菌株D2的分离鉴定及其产酶影响因素的研究

纤维素转化为可利用的物质,对于能源危机、环境污染问题的解决具有重要作用.采用羧甲基纤维素钠(CMC-Na)为唯一碳源配制培养基,采取克氏碘液染色法从常年落叶的土壤中分离、筛选高效纤维素降解菌,并对其进行形态学观察、生理生化分析、分子生物学鉴定及产酶能力研究.结果显示,共分离出4种菌株(D2,D3,D4和D5),经克氏碘染色,发现D2菌株的纤维素降解能力最强.经形态学观察、生理生化实验和16S rRNA基因测序分析,D2菌株被鉴定为一株芽孢杆菌(Bacillus sp.).为提高菌株D2的产酶量,对其发酵时间、接种量、发酵温度、培养基初始pH、摇床转速5个单因素进行研究.结果显示,当发酵温度为37℃,液体产酶培养基初始pH为7,接种量为3%及摇床转速为160 r/min时,菌株D2在发酵第3 d有最高产酶能力,纤维素酶(CMCase)活性为1.4562 U/mL.以上结果为纤维素资源的利用奠定了一定的基础.