不同密度螺-草结构对养殖尾水净化效果的比较研究

为减少水产养殖污染物排放,以苦草为对照组,构建环棱螺螺 草生态系统净化池塘养殖尾水,比较不同密度螺 草结构对养殖尾水的净化效果,同时探讨螺草互作对水质的影响。结果表明不同密度螺 草组合对养殖尾水均有较好的净化效果,以中密度组（螺密度50 ind/m3）的去除效果最优,25 d对Chl a、CODMn、TN、TP、NH4+ N、NO3- N和浊度的去除率分别达到98%、39.7%、44.2%、86.9%、58.2%、82.3%和91%,其中以17~25 d的营养物质去除率最高,水质由原来的Ⅳ类、Ⅴ类水提升为Ⅲ类水;环棱螺 苦草互作对水体的净化效果与苦草对照组差异不显著,表明其互利关系不明显;环棱螺 苦草组合对CODMn和TN的去除效果不是很理想,可能是由于实验中以黄土为底泥,其中的异养微生物较少引起的     

Salicylic acid involved in the regulation of nutrient elements uptake and oxidative stress in Vallisneria natans (Lour.) Hara under Pb stress

In this study, the alterations in nutrient elements content, reactive oxygen species level and antioxidant response were studied in leaves of Vallisneria natans (Lour.) Hara exposed to salicylic acid (SA, 10 or 100 μM), or Pb (50 μM) or their combinations for 4 d. No significant alterations in Mn and Ca content were observed but content of Cu, Zn, Fe and P decreased in plants exposed to SA alone. SA application inhibited the uptake of Pb and partially reversed Pb-induced the alterations in Mn, Ca and Fe content in leaves of V. natans exposed to 50 μM Pb. The decreased chlorophyll (a + b) and increased malondialdehyde and O²⁻ and H₂O₂ content were detected in plants exposed to 100 μM SA, 50 μM Pb, 10 μM SA + 50 μM Pb or 100 μM SA + 50 μM Pb. Application SA partially inhibited Pb-induced the increase of malondialdehyde, O²⁻ and H₂O₂ content. 100 μM SA decreased the activity of NADH oxidase and the content of non-protein thiols, carotenoids and ascorbic acid and increased the content of dehydroascorbate in plants treated with or without Pb. SA alone decreased the ascorbate peroxidase activity and increased the catalase and peroxidase activity, while SA application increased catalase activity but had no significant effect on ascorbate peroxidase and peroxidase activity in V. natans exposed to Pb. The results indicate that SA involves in the regulation of Pb uptake, nutrient balance and oxidative stress.     

不同水层光照强度对4种沉水植物生长的影响

选取金鱼藻(Ceratophyllum demersum)、轮叶黑藻(Hydrilla verticillata)、水盾草(Cabombacaroliniana)、苦草(Vallisneria gigantean)为试验材料,研究不同水层的光照强度对其存活率、株高、生物量等的影响,旨在找出这4种沉水植物在自然条件下的最...     

不同质量浓度苦草对铜绿微囊藻生长及抗氧化酶系统的影响

采用苦草（Vallisneria spiralis Linn.）和铜绿微囊藻（Microcystis aeruginosa）共生培养的实验方法,通过追踪测定铜绿微囊藻的生物量、叶绿素a含量、丙二醛（MDA）含量、超氧化物歧化酶（SOD）和过氧化物酶（POD）活性,研究了不同质量浓度苦草对铜绿微囊藻生长及抗氧化酶系统的影响。结果表明,质量浓度大于10 g/L时,苦草对铜绿微囊藻有明显的抑制作用,表现为苦草质量浓度为10、20和40 g/L时,第15天对铜绿微囊藻的抑制率分别为63.3%、94.7%和99.8%,培养过程中,铜绿微囊藻的叶绿素a含量逐渐减少,而SOD、POD活性及MDA含量呈现先增加后逐渐降低的趋势,表明苦草释放的化感物质在经过一定时间积累后能够明显抑制铜绿微囊藻SOD和POD的活性,引起细胞的氧化损伤,促进叶绿素的分解,从而导致藻类死亡,这是苦草抑制铜绿微囊藻生长的原因之一。     

EFFECTS OF CHELATED IRON ON THE GROWTH OF TWO SPECIES OF VALLISNERIA1

ABSTRACT: Iron, added as (Fe-EDTA)^-, was found stimulatory to V. spiralis at a concentration of 0.05 ppm. (Fe-EDTA)^- had no effect upon growth of V. neotropicalis as measured by changes in dissolved oxygen and dry weight. Results are compared with those derived from similar studies with Hydrilla verticillata and Egeria densa. The implications of lake drawdown and aeration are discussed.     

Vallisneria natans decomposition rates and associated macroinvertebrates,microbes and microalgae along a vertical depth gradient in an urban lake (Nanhu Lake,China)

Knowledge on aquatic macrophyte decomposition has well developed, yet the decomposition and associated biotic factors along a vertical gradient in waters remain less examined. Here, we used Vallianeria natans leaves to investigate the decomposition rate and associated decomposers and microalgae at different vertical depths, by placing V. natans leaves into litterbags (0.5 and 5?mm meshes) and incubating them at the air–water interface (AW), sediment-water (SW) interface, and 10?cm (B10) or 20?cm (B20) burial in sediment over 60 days in a littoral zone of lake. Decomposition rates decreased with increased depths in each mesh size, with significant differences among and between AW (0.028?d^?1), SW (0.022?d^?1), B10 (0.014?d^?1) and B20 (0.011?d^?1) treatments in 0.5?mm litterbags and no significant difference between B10 (0.027?d^?1) and B20 (0.025?d^?1) in 5?mm litterbags. The average contribution of macroinvertebrates to biomass loss was highest in B20 (44.66%), lowest in AW (22.66%) and midst in both SW (25.35%) and B10 (38.78%), and was much less than that of both microbes and microalgae at each location. We show the importance of macroinvertebrates, microbes and microalgae in mediating macrophyte decomposition rate in response to different vertical locations in freshwaters.     

球衣菌对重金属离子的耐受性及其吸附能力

研究了球衣菌对重金属离子Ag 、Hg2 、Pb2 、Zn2 的耐受性及生物吸附情况,并着重对Pb2 的吸附行为及工艺条件进行了探讨.结果表明:球衣菌对 4种重金属离子均有不同程度的耐受性,其中对Pb2 具有较大的耐受力.不同生长阶段的菌体对重金属离子的敏感性也不同.球衣菌对Pb2 的吸附作用是一种快速而非依赖温度的过程.在ρi(Pb2 ) =5mg/L,菌体浓度ρb=0. 2g/L,θ=30 ~35℃,pH=6. 5,菌龄a=32h,吸附时间t=30min时,吸附率可达95. 6%,吸附量为 23. 9mg/g. 图 3参 10     

改性膨润土和沉水植物联合作用处理沉积物磷

首次将改性膨润土（modified bentonite,MB）作为原位吸附材料与沉水植物苦草（Vallisneria spiralis,V.spiralis）联合处理沉积物磷.研究结果表明,MB可以促进沉水植物V.spiralis的生长, V.spiralis可能通过根系分泌作用促进溶磷或是通过促进根际微生物群落的P代谢活性增加沉积物中的生物可利用性P含量.MB与沉水植物V.spiralis对沉积物P的联合作用效果优于MB和沉水植物V.spiralis单独作用之和.厚度5cm MB和V.spiralis联合作用对沉积物TP,IP,OP,Fe/Al-P和Ca-P的去除率可达59.8%,57.1%,67.8%,66.7%和44.7%.微生物试验结果表明,厚壁菌门Erysipelotrichaceae科的菌属PSB-M-3是联合组相比单一V.spiralis组或单一MB组微生物群落P代谢功能增强的主要贡献者.本研究还首次发现了Erysipelotrichaceae科微生物可作为沉积物中潜在的除磷菌.研究结果表明MB和沉水植物联合控制沉积物磷技术可进一步应用到富营养化湖泊沉积物控制工程.     

低溶解氧对苦草生长的影响

针对太湖梅梁湾生态净化示范区内重建的沉水植物存在的腐烂死亡问题及伴随的底层水体溶解氧偏低现象,在室外模拟生态系统内进行了低氧对沉水植物（苦草）生长的影响试验。结果表明：无论沉积物类型如何,一个月的低氧处理（溶解氧平均值为1.6 mg/L）对苦草株重、株高、分蘖数及叶片数等指标的影响均不明显,对块茎的影响则较显著,表现为块茎数量与重量显著下降。对岸边沉积物处理组而言,低氧对苦草根系的影响显著,表现为根须变细且数量增加,根系活力明显下降,中心沉积物处理组则不显著。同时,低氧处理使岸边沉积物处理组的沉积物氧化还原电位显著下降、水体营养盐浓度上升,尤其是磷酸盐浓度显著增加,中心沉积物处理组的环境理化因子变幅则相对较小。分析认为,低氧对苦草生长的影响虽不明显,但对其种群扩张有潜在的不利作用;梅梁湾生态净化示范区内沉水植物的腐烂死亡,低氧的作用是次要或间接的。     

水体的营养水平对苦草(Vallisneria atans)生长的影响

在室外控制条件下,以太湖梅梁湾水体现状营养水平(ρ(TN)为5 mg/L和ρ(TP)为0.2 mg/L)为依据,研究营养盐含量升高对苦草生长的影响.结果表明:①在满足光补偿点及无种间竞争等的条件下,苦草在营养水平为ρ(TN)＞10 mg/L和ρ(TP)＞0.4 mg/L的水中也能成活.②随着营养盐含量的升高,苦草生物量的增长率逐渐降低,当水中ρ(TN)达到10 mg/L和ρ(TP)达到0.4 mg/L时,苦草的生物量开始减少;营养盐含量升高对苦草叶片特征的影响不明显,而苦草根状茎的生物量却随着营养盐含量的升高而逐渐减少,当水体营养水平达到ρ(TN)为10 mg/L和ρ(TP)为0.4 mg/L时,除叶片长度外,苦草的其他形态指标值均显著下降.③在梅梁湾水体现状营养水平的基础上,当水中磷含量增加1倍时对苦草生长造成的抑制作用大于氮含量增加1倍时;当二者均增加时,对植物生长造成的抑制作用显著增加.