铅锌尾矿砂污染下的岩溶土壤微生物群落碳源代谢特征

以广西阳朔思的村铅锌矿尾砂污染的水稻田、玉米地、柑橘园以及对照(旱地)土壤为研究对象,采用碳素利用法和18S rRNA变性梯度凝胶电泳技术探究岩溶区重金属污染下土壤微生物群落碳源代谢特征以及土壤真菌与土壤有机碳的交互关系.结果表明,广西阳朔思的村铅锌矿尾砂污染区土壤重金属总体含量(Pb、Zn、Cu、Cd)依次为:水稻田玉米地柑橘园对照;同时地累积综合指数显示该区重金属污染以Pb、Cd为主,其中Cd带来的环境风险最高.受Pb、Zn、Cu、Cd等重金属复合污染物影响,土壤微生物生物量碳、微生物熵和碳源代谢速率表现出随总体重金属质量分数增加而降低的变化规律,但土壤总有机碳质量分数却表现为:水稻田对照柑橘园或玉米地.DGGE结果进一步显示对照组土壤存在担子菌门多孔菌目Pycnoporus sp.ZW02.30,柑橘园和玉米地土壤存在镰刀菌属Fusarium solani和Fusarium oxysporum以及柑橘园土壤存在青霉属Penicillium decumbens.然而,上述参与淀粉、纤维素、半纤维素、木质素等糖类降解过程的真菌没有在水稻田土壤检出.加之,水稻田土壤微生物功能多样性指数和微生物熵最低而土壤有机碳质量分数最高,说明铅锌尾矿砂通过影响不同样地土壤微生物糖类代谢过程,进而调节土壤碳在微生物特别是真菌作用下的矿化速率.     

短程硝化工艺出水水质及微生物区系分析

实验采用短程硝化工艺处理高氨氮废水,并用PCR-DGGE分析了系统中的微生物区系。结果表明,进水氨氮浓度在50～400mg/L之间梯度增加时,出水氨氮浓度在10mg/L以下;随着氨氮浓度的增加,亚硝态氮积累率逐渐升高,当氨氮浓度达到300mg/L时,积累率达到90%左右。DGGE分析结果表明,随着运行时间的延长,微生物区系多样性减少;氨氮负荷为50mg/L与400mg/L相比,相似性为0.24。     

Spatiotemporal optical properties of dissolved organic matter in a sluice-controlled coastal plain river with both salinity and trophic gradients

Due to the combined effect of sluices and sea tide, the sluice-controlled coastal plain river would be characterized by both trophic state and salinity gradients, affecting the spatiotemporal optical properties of dissolved organic matter (DOM). In this study, we investigated the spatiotemporal variation of water quality parameters and optical properties of DOM in the Haihe River, a representative sluice-controlled coastal plain river in Tianjin, China. A significant salinity gradient and four trophic states were observed in the water body of the Haihe River. Two humic- and one protein-like substances were identified from the DOM by the three-dimensional fluorescence spectra combined with the parallel factor (PARAFAC) analysis. Pearson's correlation analysis and redundancy analysis (RDA) showed that the salinity significantly affected the abundance of chromophoric DOM (CDOM) but did not cause significant changes in the fluorescence optical characteristics. In addition, the effect of Trophic state index (TSI) on the CDOM abundance was greater than that on the fluorescence intensity of fluorescent dissolved organic matter (FDOM). In the water body with both salinity and trophic state gradients, TSI posed a greater influence than salinity on the CDOM abundance. Our results fill the research gap in spatiotemporal DOM characteristics and water quality variation in water bodies with both salinity and trophic state gradients. These results are beneficial for clarifying the joint influence of saline intrusion and sluices on the DOM characteristics and water quality in sluice-controlled coastal plain rivers.     

大通河流域土壤细菌及氮循环功能菌群沿海拔的空间分布

探究土壤微生物的海拔分布格局及其驱动机制对理解气候变化下陆地生态系统的响应至关重要.土壤微生物群落的海拔分布格局随空间尺度有所差异,为此分别沿大通河流域干流流向（海拔梯度1 000 m）和山体坡面（海拔梯度500 m）设置了两种空间尺度的样带,利用高通量测序技术分析土壤细菌群落结构和多样性沿海拔的分布特征,基于FAPROTAX数据库分析氮循环功能类群的海拔分布,探讨驱动土壤细菌群落沿海拔分布的关键环境因子.结果表明:①土壤理化性质沿海拔分布有显著差异,总氮（TN）和硝态氮（NO₃ ^-）含量与海拔正相关（P < 0.01）,土壤容重（BD）、pH与海拔负相关（P < 0.001）;②细菌群落OTU丰度沿海拔升高显著增大（P < 0.01）,丰富度和多样性指数沿海拔增大,但趋势不显著（P > 0.05）;③细菌群落以酸杆菌门（Acidobacteria）、变形菌门（Proteobacteria）和拟杆菌门（Bacteroidetes）为优势门,其相对丰度随海拔升高分别增加、减小和微弱减小;④参与氮循环的功能类群共13种,以硝化作用、好氧氨氧化和好氧亚硝酸盐氧化作用为主,随海拔升高响应规律不同,其中硝化作用细菌丰度显著增加（P < 0.01）,好氧氨氧化和硝酸还原细菌丰度微弱增加,而参与含氮化合物异化还原的细菌丰度先增后减;⑤冗余分析表明海拔（ELEV）、pH和氨氮（NH₄ ⁺）是驱动门水平土壤细菌群落的主要因子,Mantel分析表明土壤细菌氮循环优势类群均受海拔驱动（P < 0.01）.⑥流域和坡面尺度上细菌群落α-多样性沿海拔的规律一致,但土壤性质、氮循环功能菌群丰度和主要环境影响因子均不同.因此从不同空间尺度探究土壤微生物的海拔分布格局具有重要意义.     

基于PCR-DGGE的重金属污染土壤微生物种群指纹分析

采用变性梯度凝胶电泳（DGGE）分析方法,研究沈阳市细河沿岸重金属污染土壤中微生物结构多样性、种群丰富度及种群结构的动态变化规律。结果表明：直接从土壤中抽提总DNA,对16SrRNAV3可变区序列进行扩增,DGGE指纹图谱分析,微生物种群结构和变化规律明显,同时也表现为重金属污染程度越重,多样性指数越低;其中细河底泥重金属含量严重超标,多样性指数最低。经方差分析,重金属污染情况与Shannon-wiener多样性指数呈负相关,其中重金属污染对微生物的均匀度指数影响最显著,并且锌污染对其影响最大为-0.985。表明PCR-DGGE技术可以用于污染环境下微生物多样性研究,也为污染环境下土壤微生物多样性研究提供了新的实验方法与依据。     

EVALUATION OF THE ROSGEN STREAM CLASSIFICATION SYSTEM IN CHEQUAMEGON‐NICOLET NATIONAL FOREST,WISCONSIN1

ABSTRACT: Data collected from 121 stream reaches during 1991 to 1993 were evaluated to determine the applicability of the Rosgen Stream Classification System (RSCS) to the low relief terrain within the Chequamegon‐Nicolet National Forest (CNNF) in Wisconsin, USA. All reaches were classified to RSCS Level I and II except that 10.7 percent had sinuosities below the continuum limits and one reach had a predominantly organic substrate. Five of eight possible RSCS Level I types were observed including B, C, D, A, E, and F; 86 percent were C and E types. Seventeen of 94 possible RSCS Level II types were observed. Most reaches were slightly entrenched, had low to moderate width/depth ratios, relatively low sinuosity, low slope, and sand or gravel as the dominant channel material. Discriminant analyses were used to verify the applicability of RSCS for streams within the CNNF; discriminant functions correctly classified 92.5 and 94.7 percent of the Level I and II RSCS types, respectively. When limits for E and F types were modified slightly at Level II by adding an additional category for slopes less than 0.1 percent (a modification we recommend for low relief terrain), discriminant functions correctly classified 99.1 percent of the types. Adding another slope break at 0.3 percent produced similar results. Based on our analyses, RSCS works well within the CNNF and is probably applicable to other areas with low‐relief terrain.     

快速木质纤维素分解菌复合系MC1对秸秆的分解能力及稳定性

以天然水稻秸秆为材料研究了快速降解木质纤维素的细菌复合系MC1对木质纤维素的分解能力;并在不同条件保藏、高温处理以及利用变性梯度胶电泳(DGGE)技术研究了复合系的稳定性.结果表明,复合系MC1在50℃液体静止培养条件下8～10d,把培养液2%干重的水稻秸秆完全分解溶化;经过9d的培养,水稻秸秆的总干重减少81%,其中纤维素减少99%,半纤维素减少74%,木质素减少51%.连续继代培养4a、常温干燥保存4a、-20℃冷冻藏4a、培养液直接在室温和4℃保存1a、90℃处理30min仍具旺盛的分解能力并稳定传代.平板培养基培养证明MC1全部由细菌组成,16SrDNA变性梯度胶电泳(DGGE)检测结果,在6个月内主要条带几乎没有变化,说明MC1的菌种组成相当稳定.MC1对纤维素的分解利用具重要前景.     

环境升温过程对常温固化环氧树脂热力学性能的影响

目的提高常温固化环氧树脂体系的高温使用性能。方法采用常温固化剂T31、中温固化剂IPDA以及高温固化剂DDM作为混合固化剂,对E-44型和AG-80型混合环氧树脂体系进行常温固化反应,并分析环境升温过程对固化物热力学性能的影响。通过DMA分析、热变形测量、固化度测试,分别评价室温固化环氧树脂在环境升温过程前后的玻璃化转变温度、热变形量及体系内部的固化反应程度变化,并通过吸水率测试和弯曲强度测试对玻璃纤维布增强常温固化环氧树脂基复合材料的耐湿热性能以及高温条件下的力学性能进行分析。结果环氧树脂常温固化物的tg为85.21℃,经1.5℃/min的平均升温速率加热至90℃之后,该环境升温过程使固化物的固化度增大至92%以上,tg增长为132.06℃的同时热变形温度增大。其复合材料耐湿热性能提高,且100℃时弯曲强度的保持率为65%,对于加热至120℃的环境升温过程,固化物的固化度接近96%,tg增长为144.45℃的同时热变形温度进一步提高,其复合材料耐湿热性能改善程度更加明显,且130℃时弯曲强度保持率仍接近60%。结论常温、中温、高温混合固化剂的合理复配有助于环氧树脂体系在环境升温变化的诱导条件下发生梯度式固化反应,使体系内部的交联固化程度迅速升至较高水平,可以有效提高其玻璃化转变温度,显著改善常温固化环氧树脂体系在高温条件下的热力学性能。