云南红豆杉的保护和开发利用

云南红豆杉(Taxus yunnanensis W.C.Cheng&L.K.Fu)是红豆杉属植物中紫杉醇含量最高的树种,同时也是我国红豆杉属中分布最广和资源蕴藏量最丰富的物种.然而,近年来由于人为大量砍伐,云南红豆杉野生资源遭到严重破坏,加上生长缓慢且天然更新困难,目前处于濒危状态.对云南红豆杉天然资源的保护和药用人工...     

巯基化合物在万寿菊镉解毒中的作用

采用水培实验方法研究了万寿菊体内镉积累和解毒与巯基化合物含量的关系。万寿菊植株分别在镉浓度为0、0.1、0.5、2和8 mg/L的营养液中暴露7 d,测定了根、茎、叶中镉、非蛋白巯基(NPT)、半胱氨酸(Cys)、γ-谷氨酰半胱氨酸(γ-EC)、谷胱甘肽(GSH)和植物络合素(PCs)的含量。植物根、茎、叶中镉含量都随着镉暴露浓度的增加而增加。当溶液中镉浓度较低(0.1～2 mg/L)时,茎叶中NPT、PCs、Cys和γ-EC含量随着镉浓度增加而增大;当镉浓度较高(8 mg/L)时,茎叶中PCs含量迅速降低,GSH含量大幅度增高。在根部,这些巯基化合物的含量几乎不受镉处理影响,且含量较低。以上研究结果表明:PCs在万寿菊镉的解毒机制中发挥一定的作用,暴露于高浓度的镉,GSH比PCs起着更为重要的解毒作用。     

水葱修复土壤镉污染潜力的研究

野外观察与研究发现水葱(Scirpus tabernaemontani G.)可以耐受土壤中高浓度的重金属污染,并对镉(Cd)有很高的生物富集量.实验室水培试验研究了两个主要因素,营养液pH与Cd含量,对水葱生物量以及Cd富集效果的影响.结果表明,它可耐受高浓度Cd (30 mg/L)和大范围pH变化 (3.7～7.7).当营养液pH为4.7, Cd为25 mg/L时,水葱富集的Cd达到最大值:地上部分264.71 mg/kg,地下部分234.39 mg/kg,平均转运系数1.13.这显示了它用于植物修复Cd污染土壤的潜力.     

强化供氧条件下潜流型人工湿地运行特性

针对潜流型人工湿地中溶解氧浓度和脱氮率偏低的问题,试验研究了强化供氧对植物和微生物的影响及人工湿地内溶解氧浓度、净化效率的变化规律.结果表明,强化供氧宜在湿地前端进行,最佳气水比为6左右,可采用连续供氧方式.供氧对湿地植物生理特性无明显不良影响,可显著增加湿地中硝化菌、反硝化菌数量,硝化菌可比供氧前高出1～2个数量级,反硝化菌高出1个数量级.强化供氧有效改善了湿地内氧环境,供氧前湿地内溶氧浓度普遍低于0.6 mg/L,供氧后氧浓度上升至1 mg/L以上.强化供氧有利于各类污染物质尤其是有机物和氮类物质的去除,有机物去除率比原湿地高出10％左右, TN去除率能够达到60％以上.因此,强化充氧措施具有较好的研究和应用价值.     

下行流人工湿地去除生活污水中氮磷的研究

用下行流人工湿地处理生活污水,分析了系统对TP,TN的处理效果,并将有无植物2种系统对污染物的去除效果进行对比.研究结果表明:下行流人工湿地对N,P都有很高的去除率;进水中TN,TP的浓度变化对出水中N,P含量影响不大,系统对N,P有一定的抗冲击能力;植物在污染物去除过程中起了一定的作用.     

增施CO2对C3和C4植物根际氯氰菊酯残留浓度的影响

CO2减排和土壤污染修复是我国实现经济和环境可持续发展必须解决的两大难题.基于生物固碳对根际微环境的影响,本研究提出通过增施CO2强化土壤有机污染的植物修复过程,为同时解决CO2减排和土壤污染植物修复面临的困境提供新思路.在模拟的CO2增施环境中,以C3植物菜豆和C4植物玉米为供试植物,以氯氰菊酯为目标污染物,研究增施CO2对C3和C4植物根际氯氰菊酯残留浓度的影响.结果表明,增施CO2可显著增加C3植物菜豆的地上和地下干重,在氯氰菊酯添加浓度为0、20、40 mg.kg-1时地下干重分别比自然CO2水平时增加了54.3%、31.9%和30.0%.增施CO2提高了未添加氯氰菊酯土壤的菜豆根际微生物数量,但降低了添加氯氰菊酯土壤的菜豆根际微生物数量.增施CO2对未添加氯氰菊酯土壤的菜豆根际氯氰菊酯残留浓度没有显著影响,但降低了菜豆根际氯氰菊酯的残留浓度,分别比自然CO2水平时下降24.0%（20mg.kg-1）和16.9%（40 mg.kg-1）.然而,对C4植物玉米而言,增施CO2对植物生物量、根际微生物、根际氯氰菊酯残留浓度下降没有明显促进作用,甚至有抑制作用.本实验表明,增施CO2降低了C3植物根际氯氰菊酯残留浓度,可以考虑将增施CO2作为C3植物修复土壤污染的强化措施,但对C4植物的影响还有待进一步研究.     

日本森林大气中过氧化物的浓度及其对森林植物的影响

为了研究森林衰退的原因,于2000,2001和2002年的8月,分别选择出现森林衰退的日本奥日光白根山落叶树森林和未出现森林衰退的长野县大芝高原红松森林设立监测点,对光化学氧化剂臭氧(O3)和过氧化物的浓度进行监测,同时利用人工气候室对森林植物山毛榉和白桦进行了50′10-9O3、100′10-9O3和50′10-9O3+2′10-9~3′10-9过氧化物(过氧化氢(H2O2)及甲基过氧化氢(MHP))的暴露实验.野外监测结果表明,监测期间奥日光和长野的O3平均浓度相同,奥日光的H2O2及MHP平均浓度均高于长野;大气中的H2O2和MHP总是与O3共存,并且其浓度随O3浓度的增加而增加.暴露实验结果表明,暴露于50′10-9O3+2′10-9~3′10-9过氧化物的山毛榉和白桦出现了不同于O3暴露的叶片伤害症状;与100′10-9O3相比,50′10-9O3+2′10-9~3′10-9过氧化物导致植物出现了严重的叶片伤害和显著的光合速率下降.研究结果表明,除O3外,大气中的过氧化物也是导致森林衰退的原因之一.     

Phosphorus utilization and microbial community in response to lead/iron addition to a waterlogged soil

Constructed wetlands have emerged as a viable option for helping to solve a wide range of water quality problems. However, heavy metals adsorbed by substrates would decrease the growth of plants, impair the functions of wetlands and eventually result in a failure of contaminant removal. Typha latifolia L., tolerant to heavy metals, has been widely used for phytoremediation of Pb/Zn mine tailings under waterlogged conditions. This study examined e ects of iron as ferrous sulfate (100 and 500 mg/kg) and lead as lead nitrate (0, 100, 500 and 1000 mg/kg) on phosphorus utilization and microbial community structure in a constructed wetland. Wetland plants (T. latifolia) were grown for 8 weeks in rhizobags filled with a paddy soil under waterlogged conditions. The results showed that both the amount of iron plaque on the roots and phosphorus adsorbed on the plaque decreased with the amount of lead addition. When the ratio of added iron to lead was 1:1, phosphorus utilized by plants was the maximum. Total amount of phospholipids fatty acids (PLFAs) was 23%–59% higher in the rhizosphere soil than in bulk soil. The relative abundance of Gram-negative bacteria, aerobic bacteria, and methane oxidizing bacteria was also higher in the rhizosphere soil than in bulk soil, but opposite was observed for other bacteria and fungi. Based on cluster analysis, microbial communities were mostly controlled by the addition of ferrous sulfate and lead nitrate in rhizosphere and bulk soil, respectively.     

Elemental sulfur effects on Pb and Zn uptake by Indian mustard and winter wheat

A pot experiment was conducted to investigate the influence of elemental sulfur to contaminated soil on plant uptake by a heavy metal hyperaccumulator, Indian mustard( Brassica juncea ) and a field crop, winter wheat( Triticum. aestivum). Elemental sulfur(S) with different rates was carried out, they were 0(S0 ), 20(S20 ), 40(S40 ), 80(S80 ), and 160(S160 ) mmol/kg respectively. Extra pots with the same rates of S but without plants were used for soil sampling to monitor pH and CaCl2-extractable heavy metal changes. The results showed that S enhanced phytoextraction of Pb and Zn from contaminated soil. Application S effectively decreased soil pH down to 1.1 as the most at the rate of Sl60. The concentrations of CaCl2-extractable Pb and Zn in soil and uptake of Pb and Zn by the plants were increased with soil pH decreased. A good correlation between CaCl2-extractable Pb/Zn and soil pH was found( Rpb^2 = 0.847 and RZn^2 = 0,991, n = 25). With S application, soil CaCl2-extractable Pb and Zn concentrations, concentration of Pb and Zn in plants and the amount of removal by plant uptake were significanfly higher than those without S. Under the treatment of S160, the highest CaCl2-extmctable Pb and Zn were observed, they were 4.23 mg/kg and 0.40 mg/kg, 2.7 and 2.0 times as that of the control(So ) respectively. At the highest rates of S( Sl~0 ), both Indian mustard and winter wheat reached the highest uptake of Pb and Zn. The highest Pb concentrations in wheat and Indian mustard were 32.8 mg/kg and 537.0 mg/kg, all 1.8 times as that of the control, and the highest Zn concentrations in wheat and Indian mustard were 215.5 mg/kg and 404.0 mg/kg, 2.4 and 2.0 times as that of the control respectively. The highest removals of Pb and Zn from the contaminated soil were 0.41 rag/pot and 0.31 nag/pot by Indian mustard in the treatment of S160 through 50 days growth.     

三氯乙烯污染对植物、土壤生物学指标的影响

通过室内模拟实验,研究了不同浓度TCE污染对小麦幼苗叶绿素含量、超氧化物歧化酶(SOD)活性、过氧化氢酶(CAT)活性及土壤过氧化氢酶、土壤呼吸率的影响。结果表明,与对照组相比,较高浓度TCE对小麦叶绿素的合成存在着抑制作用,且抑制作用随着浓度的升高而增强。SOD与CAT活性随着TCE浓度的增加不同程度地表现出先升高后降低的趋势。TCE对土壤过氧化氢酶的抑制作用随着时间的推移能够恢复到对照水平,其浓度与酶活性之间的相关性不明显。TCE浓度大于4.00mg/kg时对土壤呼吸率的抑制作用显著,各浓度与土壤呼吸率间的剂量—效应关系明显,且土壤呼吸作用存在抑制—恢复的趋势。