纳米羟基磷灰石对重金属污染土壤Cu/Cd形态分布及土壤酶活性影响

通过室内培养实验,研究了纳米羟基磷灰石对重金属污染土壤Cu/Cd形态分布及土壤酶活性的影响。结果表明,施加纳米羟基磷灰石显著提高了土壤pH,其中3%和5%添加剂量处理60 d后使土壤pH分别提高了1.23个和1.35个单位;纳米羟基磷灰石显著减少了毒性较强的离子交换态Cu/Cd的含量,增加了毒性中等的碳酸盐结合态、铁锰氧化物结合态、有机结合态及毒性最低的残留态Cu/Cd含量,使Cu/Cd由植物可利用态向潜在可利用态转变;纳米羟基磷灰石不同程度地提高了土壤过氧化氢酶、脲酶和酸性磷酸酶活性。3种酶活性与Cu/Cd形态分布的相关性表明,过氧化氢酶和酸性磷酸酶对土壤重金属Cu/Cd活性变化比较敏感,可以作为重金属Cu/Cd污染土壤的评价指标。     

四种改良剂对铜和镉复合污染土壤的田间原位修复研究

研究了石灰、磷灰石、蒙脱石和凹凸棒石对冶炼厂周边Cu、Cd污染土壤的原位修复效果。以黑麦草(Lolium perenne L.)作为田间修复植物,采用植物重金属吸收性、土壤重金属化学提取性及土壤溶液重金属浓度变化等作指标来评价修复效果,并研究了黑麦草对Cu、Cd的吸收与土壤、土壤溶液中Cu、Cd含量的相关性。结果表明,石灰高添加剂量(石灰占污染土壤耕作层质量的0.4%)处理黑麦草对重金属的富集效果最好,显著降低了重金属毒性,促进了黑麦草的生长及其对重金属的富集;石灰和磷灰石各添加剂量均显著降低了污染土壤交换态Cu含量;石灰、磷灰石和蒙脱石各添加剂量均显著提高了土壤溶液pH并显著降低了其Cu、Cd浓度。黑麦草地上部、根中Cu浓度与土壤交换态Cu及土壤溶液Cu浓度呈显著或极显著正相关关系。     

不同钝化剂和培养时间对Cd污染土壤中可交换态Cd的影响

原位化学钝化技术是修复重金属污染土壤的重要途径之一,通过施入一些钝化剂以降低土壤中重金属有效态含量,从而减少其迁移及对植物的毒害。选取羟基磷灰石（HA）、磷矿粉（PRX和PRH）、沸石、赤泥、新鲜植物残体、玉米秸秆粉末以及相应的处理共21种钝化剂,在同一培养条件和添加浓度下,比较其对人工Cd污染土壤中可交换态Cd含量的影响,并分析了其在不同培养时间对钝化效果的时间效应,试验的结果对于筛选Cd污染土壤钝化剂有着重要的意义。结果表明,纳米化赤泥、羟基磷灰石和纳米化酸洗赤泥可显著降低土壤中可交换态Cd含量,钝化比例高达35%-55%;赤泥、酸洗赤泥、沸石达15%-25%;富含巯基植物蒜苗、油菜、大葱植物残体也可达20%-25%。磷矿粉、大葱粉末、玉米秸秆和巯基化玉米秸秆的钝化效果相对较差;HA、铵型沸石、纳米赤泥、酸洗纳米赤泥、干油菜粉末、酸洗赤泥对可交换态Cd的钝化效果的时间效应不明显;赤泥、大葱残体、特别是玉米秸秆和巯基玉米秸秆随时间增长钝化效果增加显著,在8周和16周时段钝化效果较好。     

镉胁迫下钝化剂对菠菜镉吸收累积及土壤微生物群落结构的影响

为了探究镉（Cd）胁迫下不同钝化剂对菠菜Cd吸收转运及根际微生物群落结构的影响,设置不施钝化剂（CK）、单施纳米羟基磷灰石（nHAP）、单施巯基生物炭（TMB）、配施纳米羟基磷灰石+巯基生物炭（HPTB）4个处理,比较各处理的土壤微生物群落结构、土壤化学性质与菠菜生物量及Cd含量。结果表明,各钝化剂处理下菠菜生物量均增加,Cd含量均降低;不同钝化剂对土壤主要优势菌群的组成没有显著影响,但会改变细菌和真菌的相对丰度。主成分分析表明,nHAP对细菌群落结构影响较大,对真菌群落结构影响较小。冗余分析发现,pH是影响细菌群落结构的主要因子,全磷含量是影响真菌群落结构的主要因子。综上所述,单施nHAP能够促进菠菜生长,降低Cd含量,且对微生物群落结构的影响较小。     

生物炭对铜矿区污染土壤微生物活性及香根草富集铜、镉、铅的影响

矿区土壤易发生重金属污染,是土地资源利用和维护的一大难题。以铜矿区污染土壤为研究对象,按质量比添加0,1%,2%,4%,10% (w/w)的生物炭,进行香根草室内盆栽试验。研究添加生物炭对土壤pH和微生物活性、香根草富集与转运重金属的影响,探明重金属形态含量与生物炭、微生物活性的相关性,旨在为生物炭与香根草联合修复矿区重金属污染土壤提供理论参考。结果表明:生物炭的添加能提高土壤pH,显著提高土壤FDA水解酶、蔗糖酶和脲酶活性,显著促进土壤基础呼吸,但对土壤微生物量碳无显著影响;生物炭的添加使香根草生物量显著增大,降低土壤Cu和Pb的有效态占比,Cd的变化与此相反;添加生物炭促进香根草对Cd和Pb的富集,降低香根草对Cu的富集,减少Cu、Cd和Pb在香根草体内的转运,因此香根草可作为Cu、Cd和Pb的稳定化植物。土壤蔗糖酶活性与香根草叶片Cu、Cd和Pb含量、有效态和残渣态Cu含量呈显著正相关,土壤基础呼吸与叶片Cu、Cd和Pb含量、有效态Cu、Pb含量呈显著负相关,而与有效态Cd含量呈显著正相关。总之,生物炭可减弱矿区土壤重金属对香根草生长的毒害作用,并促进香根草对重金属的富集,两者结合可改善铜矿区污染土壤的理化性质和微生物活性,有利于重金属污染土壤修复,改善土壤质量。     

紫湖溪流域重金属污染风险与植物富集特征

土壤重金属污染已成为当今农业与环境领域关注的热点。为揭示紫湖溪流域重金属(As、Cd、Cr、Cu、Mn、Ni、Pb和Zn)污染状况,该研究测定与分析了紫湖溪水体、河底淤泥和河岸土壤以及9种河岸植物的重金属含量,利用污染指数法系统评估其污染状况,进而筛选出具有富集与修复重金属污染潜力的植物。结果表明,紫湖溪水体中Cd与Mn严重超标;河底淤泥中Cd、Zn和Cu污染严重,重金属潜在生态风险:ZnCdCuPbAsNiCrMn;河岸土壤受污水与底泥泛滥影响,土壤重金属间呈显著正相关性,其中,Cd、Zn和Cu重度污染;9种优势植物对重金属的选择性吸收导致其对Cd、Cr和Pb的富集系数(BCF,bioconcentration factor)偏低,转移系数(TF,translocation factor)均小于1,表现出根部囤积型特征。早熟禾、灰绿藜和枸杞对重金属的吸收具有抵抗性,湿地生态型植物水花生与猫爪草对富集重金属具有独特优势,构树对多种重金属较强的富集与转移能力暗示了该木本植物在重金属修复技术领域的巨大应用前景。     

磷灰石等改良剂对重金属铜镉污染土壤的田间修复研究

通过田间小区试验,研究了磷灰石、石灰、木炭、猪粪、铁粉5种改良剂对Cu、Cd复合污染土壤的改良效果。结果表明,石灰、磷灰石、木炭、猪粪降低了土壤溶液中重金属Cu、Cd的含量,提高了土壤溶液的pH,但改良效果随着时间的推移不断降低。磷灰石、石灰、木炭的加入显著降低了有效态Cu含量,但对有效态Cd含量影响较小。与猪粪相比,磷灰石、石灰、木炭显著增加了黑麦草生物量,提高了对重金属Cu、Cd的吸收能力,对该污染土壤的修复具有实践应用价值。     

磷灰石等改良剂对铜污染土壤的修复效果研究——对铜形态分布、土壤酶活性和微生物数量的影响

通过田间小区试验,研究了磷灰石、石灰、木炭、猪粪、铁粉对Cu污染土壤中Cu形态分布、土壤酶活性和微生物数量的影响。结果表明:改良剂的处理减少了离子交换态Cu的百分含量,增加了碳酸盐、铁锰氧化物、有机结合态Cu的百分含量,但对残留态Cu百分含量影响不大。磷灰石、石灰、木炭显著提高了土壤过氧化氢酶、酸性磷酸酶活性和土壤pH,但对脲酶活性影响较小。改良剂不同程度地增加了土壤细菌和真菌数量,且细菌和真菌数量均与土壤pH呈正相关关系,特别是真菌,与pH的相关系数达0.90。pH是影响Cu化学形态、土壤酶活性和微生物数量的主要因素,磷灰石、石灰和木炭显著提高了土壤pH,降低Cu的活性,增加了土壤酶活性和微生物数量,对Cu污染土壤具有较好的修复效果。     

植物修复对重金属镍污染土壤微生物群落的影响

采用室内盆栽试验方法,研究了外源镍污染土壤的植物修复对土壤微生物群落的影响。试验用水稻土中添加NiSO4.6H2O(100~1 600 mg kg-1)经过12周的驯化培养后,种植了2种超累积植物和1种耐性植物,经110 d的试验后进行了植物修复后土壤微生物活性的分析。结果表明,非根区土中添加镍的质量分数为100 mg kg-1时,对土壤中细菌、真菌和放线菌总数有一定的促进作用,土壤中微生物生物量最大;当添加镍的质量分数大于100 mg kg-1时,将对土壤微生物群落造成不利的影响。在植物修复过程中,通过植物的减毒(吸收重金属)作用和根系分泌物的作用,改善了土壤微生物的生存环境,提高了土壤微生物的数量和生物量。经过植物修复后,根区土壤微生物较非根区土壤的丰富,土壤微生物群落总DNA序列多样性指数相应增加,但不同植物对根区土壤微生物的贡献是不同的。     

重金属Cd、Zn、Cu和Pb复合污染对土壤生物活性的影响

通过野外土样采集及室内培养试验(25℃),研究了云南东川铜矿区土壤酶和微生物特征,以及模拟重金属Cd、Zn、Cu、Pb复合污染对土壤微生物和酶活性的影响。结果表明,矿区土壤(距矿口0~800 m)重金属污染严重,Pb、Cd、Zn、Cu全量和有效含量是对照土壤(距矿口10 000 m)的3.7~141.0倍和2.2~773.2倍;距矿口越近,土壤有机质、有效氮、有效磷和速效钾含量及土壤pH亦越低,土壤酶活性和土壤微生物数量、微生物生物量碳和氮受到的抑制程度也显著增强。与对照土壤相比,距矿口0~800 m的土壤蔗糖酶、脲酶、酸性磷酸酶、过氧化氢酶和脱氢酶活性分别降低25.5%~47.3%、22.6%~74.2%、30.9%~83.1%、16.7%~69.1%和34.6%~92.3%;细菌、放线菌和真菌数量分别较对照下降30.5%~80.1%、8.1%~49.9%和3.3%~8.3%。土壤酶中的酸性磷酸酶和过氧化氢酶,土壤微生物中的细菌对重金属污染较为敏感。恒温(25℃)培养试验中,低量的Cd、Zn、Cu、Pb复合污染刺激了土壤酶活性和细菌、真菌、放线菌、微生物生物量碳和氮的数量,但高量的Cu、Zn、Pb、Cd复合污染使土壤酶活性、细菌、真菌、放线菌、微生物生物量碳和氮均显著下降。重金属Cd、Zn、Cu、Pb之间存在着一定的协同或拮抗作用,Cd、Zn、Cu和Pb之间在微生物生物量碳和氮上表现出明显的协同效应,Pb与Cd、Zn、Cu对细菌数量的复合效应机制为拮抗效应,Cd、Zn、Cu和Pb对真菌数量和放线菌数量的复合效应机制表现为协同效应和拮抗效应并存。     

3种有机酸对伴矿景天修复效率及土壤微生物数量的影响

伴矿景天(Sedumplumbizincicola)是一种Cd和Zn的超积累植物,常用于Cd污染土壤的植物修复。有机酸能够提高土壤重金属的有效性,促进植物对重金属的积累,对重金属污染土壤的植物修复效率具有强化作用,并对土壤微生物数量有重要影响。以河潮土和红黄泥为供试土壤,探讨了乙二胺四乙酸(EDTA)、柠檬酸、草酸对伴矿景天修复效率和土壤微生物数量的影响。结果表明,有机酸能显著提高土壤有效态Cd含量,柠檬酸处理的效果最好,河潮土和红黄泥中有效态Cd含量较单种伴矿景天分别增加72.73%,12.99%(P<0.05);伴矿景天地上部Cd含量在河潮土和红黄泥中以EDTA处理最高,在河潮土和红黄泥中分别比单种伴矿景天增加99.24%和33.32%;与单种伴矿景天相比,添加有机酸处理河潮土和红黄泥中伴矿景天修复效率显著提高。添加有机酸比单种伴矿景天显著增加土壤中微生物数量,其中柠檬酸处理河潮土中细菌和真菌数量分别增加34.38%和68.42%(P<0.05),草酸处理红黄泥中放线菌数量增加150.00%。研究结果可为重金属污染土壤的植物强化修复提供理论支撑。     

紫茎泽兰和黄顶菊入侵对土壤微生物群落结构和旱稻生长的影响

为比较入侵植物与本地植物对土壤微生态影响的差异, 探索外来植物入侵的土壤微生物学机制, 本研究通过同质园试验, 比较分析了2种入侵菊科植物(紫茎泽兰、黄顶菊)和2种本地植物(马唐、猪毛菜)对土壤肥力和微生物群落的影响, 并通过盆栽反馈试验验证入侵植物改变后的土壤微生物对本地植物旱稻生长的反馈作用。同质园试验结果表明: 2种入侵植物和2种本地植物分别对土壤微生态产生了不同的影响, 尤其是紫茎泽兰显著提高了土壤有效氮、有效磷和有效钾含量,紫茎泽兰根际土壤中有效氮含量为39.80 mg·kg^-1,有效磷含量为48.52 mg·kg^-1。磷脂脂肪酸指纹图谱结果表明, 2种入侵植物与2种本地植物相比, 较显著增加了土壤中放线菌数量, 而紫茎泽兰比其他3种植物显著增加了细菌和真菌数量。盆栽结果表明: 黄顶菊生长过的土壤灭菌后比灭菌前旱稻株高增加113%, 紫茎泽兰也使旱稻的株高增加17%。由以上结果可知, 紫茎泽兰和黄顶菊可能通过改变入侵地土壤的微环境, 形成利于其自身生长扩散的微生态环境从而实现其成功入侵。     

Effect of plant growth-promoting bacteria and soil compaction on barley seedling growth, nutrient uptake, soil properties and rhizosphere microflora

Inoculants are of great importance in sustainable and/or organic agriculture. In the present study, plant growth of barley (Hordeum vulgare) has been studied in sterile soil inoculated with four plant growth-promoting bacteria and mineral fertilizers at three different soil bulk densities and in three harvests of plants. Three bacterial species were isolated from the rhizosphere of barley and wheat. These bacteria fixed N₂, dissolved P and significantly increased growth of barley seedlings. Available phosphate in soil was significantly increased by seed inoculation of Bacillus M-13 and Bacillus RC01. Total culturable bacteria, fungi and P-solubilizing bacteria count increased with time. Data suggest that seed inoculation of barley with Bacillus RC01, Bacillus RC02, Bacillus RC03 and Bacillus M-13 increased root weight by 16.7, 12.5, 8.9 and 12.5% as compared to the control (without bacteria inoculation and mineral fertilizers) and shoot weight by 34.7, 34.7, 28.6 and 32.7%, respectively. Bacterial inoculation gave increases of 20.3–25.7% over the control as compared with 18.9 and 35.1% total biomass weight increases by P and NP application. The concentration of N and P in soil was decreased by increasing soil compaction. In contrast to macronutrients, the concentration of Fe, Cu and Mn was lower in plants grown in the loosest soil. Soil compaction induced a limitation in root and shoot growth that was reflected by a decrease in the microbial population and activity. Our results show that bacterial population was stimulated by the decrease in soil bulk density. The results suggest that the N₂-fixing and P-solubilizing bacterial strains tested have a potential on plant growth activity of barley.     

接种AM真菌对采煤沉陷区文冠果生长及土壤特性的影响

煤炭井工开采往往造成地表塌陷,导致了土壤养分贫瘠和水分缺乏,土壤沙化和水土流失,从而限制了当地矿区植被生长,而丛枝菌根真菌(arbuscular mycorrhiza fungi,AM真菌)对植被生长有促进作用。以文冠果为宿主植物,采用野外原位监测和室内分析方法,研究了未接种和接种丛枝菌根真菌对采煤沉陷区复垦植物文冠果生长和土壤特性的影响。结果表明:与未接种AM真菌处理相比,接种AM真菌显著提高了文冠果根系菌根侵染率和土壤根外菌丝密度,7月接种AM真菌文冠果的株高、冠幅和地径提高了31.89%,23.07%,9.89%。同时,9月接种AM真菌处理的根际土壤全氮、碱解氮和有机碳含量分别比对照组增加0.29g/kg、13.0mg/kg和1.4g/kg,接种AM真菌显著提高了根际土壤的含水率、总球囊霉素和易提取球囊霉素,而速效磷和速效钾的含量显著降低。相关分析结果表明,菌根侵染率、土壤根外菌丝密度与根际土壤理化性质之间存在协同反馈效应。因此,接种AM真菌促进了采煤沉陷区复垦植被文冠果的生长和土壤的改良,这对矿区水土保持、维持生态系统稳定性和持续性具有重要意义。     

Plant microcosm studies demonstrating bioremediation of cyanide toxicity by Trichoderma and Fusarium spp.

The biodegradation of cyanide by Trichoderma and Fusarium spp. growing in association with plant roots in microcosms was investigated with CN^– at 50 or 100 mg/kg. Pea and wheat seeds germinated and plants grew only when seeds were inoculated with the fungi, probably because the plant/fungal association was capable of promoting cyanide catabolism. Inoculation by fungi also increased plant shoot lengths and the biomass of shoots and root compared with control plants without CN^– and fungi. Such plant/fungal association shows potential as a land remediation system.     

植物促生菌接种对中国芥蓝根际固有微生物群落结构的影响

Plant growth-promoting rhizobacteria (PGPR) have been widely recognized as an important agent,especially as a biofertilizer,in agricultural systems.The objectives of this study were to select efective PGPR for Chinese kale (Brassica oleracea var.alboglabra) cultivation and to investigate the efect of their inoculation on indigenous microbial community structure.The Bacillus sp.SUT1 and Pseudomonas sp.SUT19 were selected for determining the efficiency in promoting Chinese kale growth in both pot and field experiments.In the field experiment,PGPR amended with compost gave the highest yields among all treatments.The Chinese kale growth promotion may be directly afected by PGPR inoculation.The changes of microbial community structure in the rhizosphere of Chinese kale following PGPR inoculation were examined by denaturing gradient gel electrophoresis (DGGE) and principal coordinate analysis.The DGGE fingerprints of 16S rDNA amplified from total community DNA in the rhizosphere confirmed that our isolates were established in the rhizosphere throughout this study.The microbial community structures were slightly diferent among all the treatments,and the major changes depended on stages of plant growth.DNA sequencing of excised DGGE bands showed that the dominant species in microbial community structure in the rhizosphere were not mainly interfered by PGPR,but strongly influenced by plant development.The microbial diversity as revealed by diversity indices was not diferent between the PGPR-inoculated and uninoculated treatments.In addition,the rhizosphere soil had more influence on eubacterial diversity,whereas it did not afect archaebacterial and fungal diversities.     

外源铬对小白菜(Brassica chinensis L.)根际土壤微生物生物量和磷脂脂肪酸的剖面分布特征的影响

The effects of root activity on microbial response to cadmium （Cd） loading in the rhizosphere are not well understood. A pot experiment in greenhouse was conducted to investigate the effects of low Cd loading and root activity on microbial biomass and community structure in the rhizosphere of pakchoi （Brassica chinensis L.） on silty clay loam and silt loamy soil. Cd was added into soil as Cd（NO3）2 to reach concentrations ranging from 0.00 to 7.00 mg kg-1. The microbial biomass carbon （MBC） and community structure were affected by Cd concentration, root activity, and soil type. Lower Cd loading rates （〈 1.00 mg kg-1） stimulated the growth of pakchoi and microorganisms, but higher Cd concentrations inhibited the growth of microorganisms. The content of phospholipid fatty acids （PLFAs） was sensitive to increased Cd levels. MBC was linearly correlated with the total PLFAs. The content of general PLFAs in the fungi was positively correlated with the available Cd in the soil, whereas those in the bacteria and actinomycetes were negatively correlated with the available Cd in the soil. These results indicated that fungi were more resistant to Cd stress than bacteria or actinomycetes, and the latter was the most sensitive to Cd stress. Microbial biomass was more abundant in the rhizosphere than in the bulk soil. Root activity enhanced the growth of microorganisms and stabilized the microbial community structure in the rhizosphere. PLFA analysis was proven to be sensitive in detecting changes in the soil microbial community in response to Cd stress and root activity.     

Changes in rhizosphere microbial activity mediated by native or allochthonous AM fungi in the reafforestation of a Mediterranean degraded environment

This study was carried out in a semiarid degraded area to assess the effectiveness of mycorrhizal inoculation with a mixture of native arbuscular mycorrhizal (AM) fungi or an allochthonous AM fungus (Glomus claroideum), on the establishment of Olea europaea subsp. sylvestris L. and Retama sphaerocarpa (L.) Boissier in this area. Associated changes in the soil microbiological properties and aggregate stability related to these AM inocula were also recorded. Eighteen months after planting, G. claroideum had increased available P in the rhizosphere of both shrub species. In general, both inoculation treatments increased water-soluble C and water-soluble and total carbohydrates, G. claroideum being the most effective inoculum, particularly in R. sphaerocarpa. The mixture of native AM fungi was the most effective treatment for increasing the aggregate stability of R. sphaerocarpa soil, while that of O. europaea was increased only by G. claroideum. Increased (dehydrogenase, urease, protease-BAA, acid phosphatase and -glucosidase) enzyme activities, in particular of dehydrogenase and acid phosphatase, were recorded in the rhizosphere of both mycorrhizal shrub species. The mixture of native AM fungi was the most effective treatment for stimulating the growth of O. europaea and R. sphaerocarpa (11.6-fold and 3.3-fold, respectively, greater than control plants). The establishment of mycorrhizal shrub species favoured the reactivation of soil microbial activity, which was linked to an increase in aggregate stability.     

Grazing of protozoa on rhizosphere bacteria alters growth and reproduction of Arabidopsis thaliana

Plant roots are densely colonized by bacteria which form the basis of the rhizosphere bacterial food web with protozoa as most effective predators. We established a well defined laboratory system with Arabidopsis thaliana as model plant allowing to investigate in detail the effect of rhizosphere interactions on plant performance. We used this system to analyse separate and combined effects of natural rhizobacteria and the protozoa Acanthamoeba castellanii on plants.Protozoa and bacteria increased plant growth with the effect of protozoa markedly exceeding that of bacteria only. Arabidopsis immediately responded to the presence of protozoa by increasing carbon but not nitrogen uptake. Later protozoa enhanced plant uptake of nitrogen from organic material and prolonged vegetative growth of Arabidopsis resulting in strongly increased seed production. It is concluded that the immediate plant response was based on changes in rhizosphere signalling inducing increased plant carbon fixation rather than on protozoa-mediated increase in nitrogen availability. The subsequently increased plant nitrogen uptake presumably originated from nitrogen fixed in bacterial biomass made available by protozoan grazing, i.e. the microbial loop in soil. The results suggest that Arabidopsis prepared for the upcoming mobilization of nitrogen by increasing carbon fixation and root carbon allocation which paid-off later by increased nutrient capture and strongly increased plant reproduction.