丰水期东洞庭湖超微型浮游藻类时空分布特征及其影响因子

超微型浮游藻类(3μm)主要包括超微蓝藻(PCY)和超微真核藻(PPEs),是浮游生态系统的重要组成部分,在水体物质循环和能量流动中起着重要作用.为了解通江湖泊中超微藻动态变化特征及其关键影响因子,于2019年洞庭湖丰水期(5～8月)每月对东洞庭湖进行采样调查,研究了丰水期间东洞庭湖超微藻生物量和丰度的时空演变规律及其与环境因子的关系.结果表明,东洞庭湖丰水期超微藻生物量和丰度均表现出显著的时空演变规律(P0.05).整个丰水期间,超微藻Chla平均浓度为8.52μg·L~(-1),其对总浮游藻类Chla的贡献率平均为41.6%;从5～8月,随着水温的增加,超微藻Chla浓度不断增加,尤其是东洞庭湖北部湖区和南部湖区;东部行洪道超微藻Chla浓度全湖最低.PCY是东洞庭湖超微藻的主要优势藻,其丰度平均是PPEs的3.4倍.PCY和PPEs丰度表现出相似的时空分布规律:时间上,从5～8月均呈现先增加后降低的趋势;空间上,随着丰水期的推移,超微藻丰度峰值由北部湖区向南部湖区迁移,到8月丰水期末期超微藻丰度逐渐降低,北部湖区超微藻丰度最高.分析结果表明,丰水期超微藻表现出了显著的时空分布规律,水位和N∶P比是影响东洞庭湖PCY和PPEs丰度组成比例变化最重要的因子.     

菌群条件下铜绿微囊藻休眠体复苏期间光合效率变化

将3株冲天湖底泥优势菌(Exiguobacterium.sp013、Bacillus.spD06与Bacillus.spD24)按不同配比与铜绿微囊藻休眠体用底泥包埋,在梯度温度下(10、15、20和25℃)进行复苏模拟实验.结果表明,在15、20和25℃条件下,菌组和无菌组铜绿微囊藻休眠体均能从底泥复苏进入上覆水体,但菌组复苏率显著高于无菌组(p0.05).在10℃条件下,菌组铜绿微囊藻休眠体能复苏,而无菌组不能.在20和25℃时,菌组对铜绿微囊藻休眠体光合系统的光合效率F_v/F_m无显著提升作用(p 0.05),而在10和15℃时,菌组能显著提升铜绿微囊藻休眠体的光合效率F_v/F_m(p0.05),且菌组Mix-4的提升能力显著强于其他菌组和无菌组.基因测序和KEGG富集分析发现,15℃时菌组Mix-4差异表达的基因显著富集于Cell cycle通路中,包括氧化磷酸化(ATP生成反应)通路和内质网蛋白合成通路,同时与光合作用相关的蛋白基因psaB、psbA及rbcL的表达量均发生显著上调,这可能是Mix-4菌群在较低温度下(15℃)提升铜绿微囊藻休眠体光合效率F_v/F_m并促进其复苏的分子机理.     

固定化溶藻菌除藻效果研究

为了解固定化溶藻菌对藻类污染水源的治理效果,模拟动态膜生物反应器,将溶藻细菌RZ14菌株固定于膜组件,通过膜自生功能形成溶藻菌生物膜。采集水华水体作为进水水样,对水体中叶绿素a、有机质、氨氮及总磷变化进行跟踪测定。结果表明:结合DMBR工艺,投加溶藻菌RZ14菌株后,叶绿素a含量低于0.05mg/L,去除率接近100%,COD及BOD5去除率分别为50.08%和71.24%,氨氮及总磷去除率分别为70.73%和86.79%。将溶藻菌投加动态膜生物反应器,能快速消除水华现象,改善水质污染状况,对藻类污染水体治理效果显著。     

利用光微生物燃料电池实现养猪废水资源化利用研究

采用光合细菌和微藻分别作为阳极和阴极接种物构建了双室光微生物燃料电池,考察了氮、磷浓度及阳极处理后的养猪废水对阴极微藻生长的影响,探讨了构建的光微生物燃料电池产电性能及去除养猪废水中COD、氨氮和总磷的效果.结果表明,阴极微藻不仅能利用无机硝态氮和氨氮,而且更喜好有机氮尿素;此外,阴极微藻可适应较高浓度的氮(250 mg·L-1)和磷(64.8 mg·L-1).构建的光微生物燃料电池以养猪废水为基质,外载为1000Ω时,稳定输出电压为161 m V;养猪废水的COD、氨氮及总磷去除率分别为91.8%、90.2%和81.7%.养猪废水经阳极光合细菌处理后培养微藻16 d,藻细胞光密度(OD680)可达3.40,略低于对照BG11培养基.因此,构建的光微生物燃料电池在处理养猪废水产电的同时,可收获微藻实现养猪废水资源化.     

Isolation,identification and desulfurization mechanism of a sulfur-oxidizing bacterium with salt tolerance北大核心CSCD

Micro-organism with efficient desulfurization performance is a key factor in the biological desulfurization technology. This study aimed to seek such a sulfur-oxidizing strain and understand its desulfurization mechanism. Wastewater in a sewage station of natural gas purification plant was used to screen the sulfide-oxidizing strain, and to identify it based on sequence similarity analysis of 16S rDNA and the morphological characteristics. Thiosulfate was used as substrate for investigating the sulfur oxidation performance and salinity tolerance; the OD600, content change of thiosulfate, sulfate, sulfur, pH and total alkalinity in the cultural system were also investigated. The strain DS-B was found to share the highest sequence similarity with Thioalkalivibrio thiocyanoxidans ARh2, therefore determined as Thioalkalivibrio. At the optimum temperature of 35 °C for growth and degradation, the removal efficiency of thiosulfate could reach 98.7% after 7 days. Strain DS-B had strong resistance to thiosulfate, and the optimal concentration of S2O32- was 2 × 104 mg/L. The analysis for sulfur oxides showed that it could oxidize thiosulfate by the pathway of S2O32-→SO42- / S2O32- → S → SO42-. Therefore the strain DS-B is a sulfur-oxidizing bacterium with great application prospect for its strong salt tolerance and conspicuous removal capability for thiosulfate.     

芽孢杆菌SeRB-2还原亚硒酸盐的动力学研究

微生物还原亚硒酸盐的动力学研究具有重要的现实意义,可以为Se (IV)污染场地的微生物修复设计提供理论依据。本文研究了兼性厌氧菌Bacillus sp.SeRB-2对亚硒酸钠的还原动力学。通过指数方程模型、对数方程模型和米氏方程模型的分析可知,Se (IV)的细菌还原符合一级反应动力学,还原反应主要集中在对数期和稳定生长前期,米氏方程模型能更好的反映细菌对亚硒酸盐的还原过程。通过对不同Se (IV)浓度下的米氏常数(K_m)和最大反应速率(V_max)的分析发现,当Se (IV)浓度较低时,K_m值较小,V_max值较大,这表明Se (IV)浓度越低,还原亚硒酸盐的酶与Se (IV)的结合能力越强,此时细菌对亚硒酸盐的还原速率越大、还原效率也越高。在本研究中,当Se (IV)浓度为1 mmol/L时,其还原效率最高可达90%,能够有效去除或降低Se (IV)污染,说明该菌在Se (IV)污染场地的生物修复上具有应用潜力。     

Characterization of a salt-tolerant bacterium Bacillus sp. from a membrane bioreactor for saline wastewater treatment

High salt concentrations can cause plasmolysis and loss of activity of cells, but the salt-torlerant bacterium can endure the high salt concentrations in wastewater. In this research 7 salt-torlerant bacteria, which could survive in dry powder products and could degrade organic contaminants in saline wastewater, were isolated from a membrane bioreactor. The strain NY6 which showed the fastest growth rate, best property for organic matter degradation and could survive in dry powder more than 3 months was selected and characterized. It was classified as Bacillus aerius based on the analysis of the morphological and physiological properties as well as the 16 S rRNA sequence and Neigh borjoining tree. The strain NY6 could survive in the salinity up to 6% and the optimal growth salinity is2%; it belongs to a slightly halophilic bacterium. The capability of its dry powder products for COD removal was 800 mg COD/(g·day) in synthesized saline wastewater with salinity of 2%. According to salt-tolerant mechanism research, when the salinity was below 2%, the stain NY6 absorbed K+and Na+to maintain osmotic equilibrium, and when the salinity was above 2%, the NY6 kept its life by producing a large amount of spores.     

固定化高效降解菌处理PTA废水的研究

研究了聚乙烯醇(PVA)加少量海藻酸钠及SiO2、CaCO3的方法固定高效菌处理PTA污水.结果表明,采用质量分数分别为PVA 10%、海藻酸钠0.3%、特种菌种10%、SiO2 3%、CaCO30.3%,用饱和硼酸溶液(pH为4.0)作为交联剂,制得的颗粒处理PTA废水时,废水COD负荷为2.91kg/m3·d时,CODcr、TOC、TA去除率均为85%以上;废水COD负荷为12.2kg/m3j·时,CODcr去除率仍为50%以上、TOC去除率为60%以上,当pTA废水pH从55降至35时,CODcr、TOC、TA去除率仍在86%以上.     

沉降法测定大气细菌粒子含量公式的检验

在沈阳市对文献［６］提出的由大气细菌粒子的沉降量计算大气细菌粒子含量的公式进行了检验．结果表明，在同泽小学由公式计算的大气细菌粒子的含量为３３２４个／ｍ３，Ａ·Ｓ采样器测定的大气细菌粒子的含量为３７９２个／ｍ３，二者之间的比值为０．９，ｔ＝０．７８５，Ｐ＞０．０５，两种方法得出的大气细菌粒子的含量没有明显差异，比传统的奥梅梁斯基公式有比较好的准确性和实用性．     

Leaf area development, dry weight accumulation and solar energy conversion efficiencies of Phaseolus vulgaris L. under different soil moisture levels near Nairobi, Kenya

Leaf area development, dry weight accumulation and solar energy conversion efficiencies of Phaseolus vulgaris L. cv GLP-2 under two soil moisture levels in two contrasting seasons near Nairobi, Kenya were investigated. The experiment confirms that dry weights and yields of Phaseolus vulgaris are limited by a drought induced decrease in leaf area, leading to less radiation interception as a source for assimilation. However, photosynthetic efficiency in Phaseolus vulgaris also appears to decrease and to contribute to these effects. Finally, an even larger decreases of economic efficiency as obtained in the second season, where stress lasted much later into the season, reveals that such a drought also limits considerably the partitioning and translocation of assimilates to the seeds of Phaseolus vulgaris. The efficiencies obtained are in line with the better literature data for other crops.