丛枝菌根真菌对铜尾矿上植物生长和矿质营养的影响

通过温室盆栽试验研究了白三叶草(Trifolium repens Linn)和黑麦草(Lolium perenne L.)在单独和混合种植情况下单独或混合接种丛枝菌根真菌Glomus mosseae和Glomus versiforme对铜尾矿砂中植物生长和矿质营养的影响.试验结果表明,不同接种处理下均以单独种植白三叶草菌根侵染率较高,平均为25%.在单种和混种情况下,接种处理均显著提高了白三叶草地上部的干物重,但对黑麦草生长影响不明显同时,接种处理显著提高了三叶草植株中的磷含量,同时降低了植株铜含量,但对黑麦草植株体内元素含量影响不明显.两种植物混合种植情况下黑麦草显示了相对竞争优势,而菌根共生体能够提高三叶草的竞争能力.试验初步证明丛枝菌根真菌对于豆科植物适应铜尾矿复合逆境(养分贫瘠和重金属污染),以及在尾矿上重建具有物种多样性的植被具有潜在作用,但有必要进一步筛选耐性菌株,并验证自然条件下菌根真菌的作用潜力.     

接种丛枝菌根真菌对露天矿区不同配比沙土与黏土的培肥效应分析

在室内盆栽条件下,研究沙土和黄土配比联合接种AM真菌对根际土壤养分、有机质含量,植物叶片营养元素含量等的影响。结果表明:接种AM真菌后玉米的生物量和叶片营养元素含量均呈现不同程度的提高,沙土与黄土质量比为1∶1和3∶1中接菌处理的提高作用较为显著;接菌后土壤中的速效磷和速效钾含量降低的同时有机质含量增加。将黄土和沙土进行优化配比可以显著提高菌根侵染率和玉米的生物量,提高土壤速效磷和有机质的含量,提升玉米叶片的营养元素含量。相关性分析表明,菌根侵染率与土壤各理化指标之间存在相互的正效应,菌根侵染后对植物营养吸收具有协同作用。     

接种菌根对根际微生物群落和磷营养的影响

以白三叶草和紫花苜蓿为供试植物,采用三室装置对不同接种处理的根际土壤微生物数量以及磷营养状况进行了研究.研究结果表明,接种混合茵根真菌的侵染率显著高于其他两种接种单一菌根真菌的处理.接种菌根对植物生长以及根际土壤微生物群落数量的促进作用均较为明显,三种接种处理植物之间的生物量差异不大,接种AM菌根促进了细茵和放线茵数量的增加,对真菌数量略有促进.接种菌根对根际土壤磷吸收有显著的促进作用,有利于植被的生长,为进一步的生态恢复与生物多样性研究奠定理论基础.     

丛枝菌根真菌在大同矸石山绿化中的应用研究

以大同矿区3个煤矿的矸石山作为实验点,选择火炬树等5种植物以及Glomus mosseae、Glomus intraradices、Glomus versiforme 3种丛枝菌根真菌,在野外自然条件下进行了接种实验,并通过测定植物的菌根侵染率、成活率、叶片相对含水量以及新梢生长量,研究接种菌根与植物的亲和程度以及对植物生长的促进效应。研究数据表明,在大同矸石山上接种的丛枝菌根真菌与植物的亲和程度良好,对植物的成活率、抗旱性以及生长量方面都有显著的促进作用。     

大同晋华宫矿煤矸石山丛枝菌根植物多样性的调查

煤矸石是煤炭生产和加工过程中产生的主要固体废弃物,煤矸石在矿区附近堆积形成煤矸石山。本文以大同晋华宫矿煤矸石山的植物多样性为基础,调查研究了每种植物根系的丛枝菌根真菌的侵染情况。结果表明,所研究的27种植物属11科,23属,其中26种为菌根植物,占到所研究植物的96.3%。多年生草本和灌木类植物根系的丛枝菌根真菌侵染率及侵染强度较高,一年生或一二年生草本植物相对较低;豆科、禾本科和菊科植物为优势种且菌根侵染率及侵染强度较高,蒺藜科蒺藜(Tribulus terrestris)没有发现被侵染现象;须根系植物的菌根侵染率及侵染强度较高,直根系植物较低。丛枝菌根真菌的侵染率和侵染强度与宿主植物的生活型和根系类型有一定的关系。     

丛枝菌根真菌和两株细菌对土壤中DEHP降解及绿豆生长的影响

采用绿豆为供试植物,通过温室盆栽试验研究接种丛枝菌根(arbuscular mycorrhiza,AM)真菌与DEHP降解菌对DEHP污染土壤的修复作用以及对植物生长的影响.试验土壤中添加DEHP含量为100mg·kg-1,试验设AM真菌Acaulospora laelis 90034、降解菌Bacillus sp.DW1和Gordonia sp.DH3单独接种以及互相组合的联合接种处理,同时设置不接种的对照处理(CK).苗后60 d收获植株.结果表明,AM真菌能很好的侵染绿豆的根系,菌根侵染提高了绿豆地上部分的干重,而对根系的干重则没有显著的影响;同时菌根侵染也促进了绿豆的P营养.但接种DW1与DH3对菌根侵染率与绿豆生长都没有显著影响.3种菌剂无论是单独或者联合接种都能显著促进土壤中DEHP的降解,3种菌剂同时接种则对DEHP的降解能达到最好的协同作用,同时也减少DEHP在绿豆地上部分的累积,这为DEHP污染农田土壤的植物修复提供了理论依据.     

三种除草剂对VA菌根真菌的侵染和植物生长的影响

用不灭菌的壤质黄潮土,在盆栽条件下研究了三种除草剂对VA菌根侵染和植物生长的影响。结果表明,三种除草剂的影响程度依次为绿麦隆>二甲四氯>氟乐灵;对菌根侵染的影响只出现在植物生长早期。接种VA菌根后,菌根侵染率、植物生长量、氮磷吸收量都显著大于不接种的对照植物。     

丛枝菌根真菌及猪炭对多氯联苯污染土壤的联合修复作用

选用玉米(Zea mays L.)为供试植物,采用盆栽试验研究了接种丛枝菌根(Arbuscular mycorrhiza,AM)真菌(Funneliformis mosseae)和添加不同粒径猪炭对多氯联苯(Polychlorinated biphenyls,PCBs)污染土壤的联合修复效应及其对土壤微生物的影响.结果表明,接种AM真菌(10%接种量)及添加2.5%猪炭对土壤有效磷含量提高具有显著的协同效应,猪炭还显著提高了土壤有机碳、速效钾含量和pH值(p0.05);猪炭显著促进了菌根真菌侵染率,但对玉米根系生物量具有抑制作用.接种AM真菌的同时添加猪炭提高了细菌16S rDNA丰度,且接种AM真菌同时添加粒径0.25 mm猪炭显著促进了土壤PCBs降解率.AM真菌与猪炭改变了土壤微生物种群的相对丰度,其中,Planctomycetes与土壤三氯联苯降解显著相关(r=0.049,p0.05),而Acidobacteria与五氯联苯降解显著相关(r=0.008,p0.01).AM真菌及猪炭提高了土壤有效养分含量,促进了植物生物量和土壤PCBs降解,对PCBs污染土壤具有较好的修复潜力.     

丛枝菌根真菌对稀土尾矿中大豆生长和稀土元素吸收的影响

采用温室盆栽试验的方法,研究了接种丛枝菌根(arbuscular mycorrhiza,AM)真菌Glomus versiforme对稀土尾矿上大豆(Glycine max)生长、矿质营养吸收、C∶N∶P生态化学计量比、重金属和稀土元素吸收的影响,旨在为稀土尾矿废弃地的生态重建和植被恢复提供基础依据.结果表明,AM真菌G.versiforme与大豆成功建立了互惠共生关系,具有较高的菌根侵染率,平均为67%.接种G.versiforme显著增加了大豆植株地上部和根部的干重,显著提高了大豆植株中P和K的含量,降低了C∶N∶P计量比,符合生长速率假设.接种G.versiforme显著降低了大豆地上部Fe和Cr的浓度,增加了根部Cd的浓度,未显著影响其它重金属的浓度;同时,显著降低了大豆植株地上部和根部轻稀土元素La、Ce、Pr和Nd的浓度.试验初步证明AM真菌对于大豆适应稀土尾矿复合逆境,以及在稀土尾矿上重建植被具有潜在的作用,应进一步验证自然条件下AM真菌的作用潜力.     

丛枝菌根真菌在矿区生态环境修复中应用及其作用效果

针对煤矿区生态环境修复中存在的主要问题,研究丛枝菌根真菌与紫穗槐共生状况,丛枝菌根真菌对紫穗槐根系发育的影响及其对煤炭开采塌陷区退化土壤的改良效应.结果表明,接种菌根5个月后,接种丛枝菌根促进紫穗槐地上部分和根系生长,提高了紫穗槐根系侵染率;接种区紫穗槐根际土壤中球囊霉素、易提取球囊霉素含量显著增加;接种菌根提高了紫穗槐根际土壤有效磷和有机质含量,微生物数量明显提高,取得较好的菌根生态效应.接种菌根有利于对矿区根际土壤的改良,促进了矿区生态系统稳定,对维持矿区生态系统的持续性具有重要意义.     

Molecular diversity of arbuscular mycorrhizal fungi at a large-scale antimony mining area in southern China

Arbuscular mycorrhizal fungi(AMF) have great potential for assisting heavy metal hyperaccumulators in the remediation of contaminated soils. However, little information is available about the community composition of AMF under natural conditions in soils contaminated by antimony(Sb). The objective of this study was to investigate the characteristics of AMF molecular diversity, and to explore the effects of Sb content and soil properties on the AMF community structure in an Sb mining area. Four Sb mine spoils and one adjacent reference area were selected from around the Xikuangshan mine in southern China. The association of AMF molecular diversity and community composition with the rhizosphere soils of the dominant plant species was studied by Polymerase Chain Reaction-Denaturing Gradient Gel Electrophoresis(PCR-DGGE). Results from all five studied sites showed that the diversity of AMF decreased with increasing Sb concentration. Principal component analysis(PCA) indicated that the AMF community structure was markedly different among these groups. Further redundancy analysis(RDA) showed that Sb contamination was the dominating factor influencing the AMF community structure in the Sb mine area. However, the multivariate analysis showed that, apart from the soil Sb content, extractable nitrogen content and organic matter content also attributed to AMF sequence distribution type. Some AMF sequences were only found in the highly contaminated area and these might be ideal candidates for improving phytoremediation efficiency in Sb mining regions. Gene sequencing analysis revealed that most species were affiliated with Glomus, suggesting that Glomus was the dominant AMF genus in the studied Sb mining area.     

Arbuscular mycorrhizal fungi alter the response of growth and nutrient uptake of snap bean（Phaseolus vulgaris L.） to O_3

The effects of arbuscular mycorrhizal fungi (AMF) Glomus mosseae on the responses to elevated O3 in growth and nutrition of snap bean (Phaseolus vulgaris L. cv Guangzhouyuan) were investigated. Exposure was conducted in growth chambers by using three O3 concentrations (20 (CF), 80 (CFO1) and 120 nL/L (CFO2); 8 hr/day for 75 days). Results showed that elevated O3 slightly impacted overall mycorrhizal colonization, but significantly decreased the proportional frequency of hypha and increased the proportional frequency of spores and vesicles, suggesting that O3 had significant effects on mycorrhizal structure. Elevated O3 significantly decreased yield, dry mass and nutrient contents (N, P, K, Ca and Mg) in both non-mycorrhizal and mycorrhizal plants. However, significant interactive effects were found in most variables due to that the reduction by O3 in the mycorrhizal plants was less than that in the non-mycorrhizal plants. Additionally, AMF increased the concentrations of N, P, Ca, and Mg in shoot and root. It can be concluded that AMF alleviated detrimental effects of increasing O3 on host plant through improving plant nutrition and growth.     

外加不同铁源和丛枝菌根对砷污染土壤上玉米生长及磷、砷吸收的影响

通过盆栽模拟试验研究了添加不同铁源及接种丛枝菌根真菌(Arbuecular mycorrhizal fungi,AMF)对高砷污染土壤上玉米生长及其吸收磷、砷、铁、锰、铜和锌的影响.试验结果表明,与对照相比,添加硫酸亚铁并接种AMF显著地提高了土壤有效铁、锰含量,降低了土壤中水溶性砷、磷含量以及玉米地上部砷的含量,并极大地增加了植株对磷的吸收,提高了植株体内磷砷吸收量之比,从而明显地改善了植株的菌根建成和生长状况.在不接种情况下,硫酸亚铁和石灰混合处理显著地降低了土壤水溶性砷、磷含量及根系砷含量,并明显增加了磷的吸收以及磷、砷吸收量的比值,使玉米植株生物量和根长增加的幅度较其它铁源处理时更大.尽管添加铁尾矿砂增加了土壤水溶性磷的含量以及植株磷的吸收而在一定程度上改善了玉米的生长,但这种效果以不接种时更为明显,因而有必要根据土壤的污染程度调整铁尾矿砂的添加量和接种抗性菌株,以强化植物的抗砷能力.     

钙和钙离子通道阻断剂对丛枝菌根真菌吸收镉的影响

本试验以三叶草(Trifolium repense L.)为宿主植物,Glomusintra radices为供试菌种,通过分室系统将外生菌丝与植物根系分隔开,并对菌丝室加以不同含量水平的Ca2+、Cd2+和Ca2+通道阻断剂(Verapamil、LaCl3)进行处理,研究在菌丝吸收过程中Cd2+与Ca2+以及Ca2+通道之间的关系.试验结果表明,高Cd2+和LaCl3处理可促进菌丝发育;高Cd2+和Verapamil、LaCl3处理不同程度地降低了菌丝对Ca2+的吸收;高Ca2+和LaCl3处理则可提高菌丝对Cd2+的吸收.根据本试验结果可以认为,Cd2+在菌丝上的跨膜转运不是通过Ca2+通道完成,而且高Ca2+水平有利于Cd2+被菌丝吸收.     

Arbuscular mycorrhizal fungi, rhizobia, available soil P and nodulation of groundnut (Arachis hypogaea) in Zimbabwe

Arbuscular mycorrhizal fungal (AMF) colonization and nodulation of groundnut were examined in nine soils collected from subsistence farmers’ fields in Zimbabwe. Nodule number, shoot dry weight, shoot N and P contents, and AMF colonization were assessed after 6 weeks growth. Both nodule number and AMF colonization differed by an order of magnitude among the nine soils. Soil available P explained almost all the variability in nodule number (r² = 0.98), but had no significant effect on percent AMF colonization. By adding P to one soil, nodule numbers increased four-fold resulting in a significantly higher N content in the shoots. Similar, but smaller, effects were obtained by increasing the abundance of AMF through an inoculation with Glomus intraradices, suggesting that nodulation in this soil was limited by AMF abundance and that the fungi could, to a limited extent, substitute for P fertilizer.     

Molecular diversity of arbuscular mycorrhizal fungi at a large-scale antimony mining area in southern China

Arbuscular mycorrhizal fungi (AMF) have great potential for assisting heavy metal hyperaccumulators in the remediation of contaminated soils. However, little information is available about the community composition of AMF under natural conditions in soils contaminated by antimony (Sb). The objective of this study was to investigate the characteristics of AMF molecular diversity, and to explore the effects of Sb content and soil properties on the AMF community structure in an Sb mining area. Four Sb mine spoils and one adjacent reference area were selected from around the Xikuangshan mine in southern China. The association of AMF molecular diversity and community composition with the rhizosphere soils of the dominant plant species was studied by Polymerase Chain Reaction-Denaturing Gradient Gel Electrophoresis (PCR-DGGE). Results from all five studied sites showed that the diversity of AMF decreased with increasing Sb concentration. Principal component analysis (PCA) indicated that the AMF community structure was markedly different among these groups. Further redundancy analysis (RDA) showed that Sb contamination was the dominating factor influencing the AMF community structure in the Sb mine area. However, the multivariate analysis showed that, apart from the soil Sb content, extractable nitrogen content and organic matter content also attributed to AMF sequence distribution type. Some AMF sequences were only found in the highly contaminated area and these might be ideal candidates for improving phytoremediation efficiency in Sb mining regions. Gene sequencing analysis revealed that most species were affiliated with Glomus, suggesting that Glomus was the dominant AMF genus in the studied Sb mining area.     

Molecular diversity of arbuscular mycorrhizal fungi at a large-scale antimony mining area in southern China

Arbuscular mycorrhizal fungi (AMF) have great potential for assisting heavy metal hyperaccumulators in the remediation of contaminated soils. However, little information is available about the community composition of AMF under natural conditions in soils contaminated by antimony (Sb). The objective of this study was to investigate the characteristics of AMF molecular diversity, and to explore the effects of Sb content and soil properties on the AMF community structure in an Sb mining area. Four Sb mine spoils and one adjacent reference area were selected from around the Xikuangshan mine in southern China. The association of AMF molecular diversity and community composition with the rhizosphere soils of the dominant plant species was studied by Polymerase Chain Reaction-Denaturing Gradient Gel Electrophoresis (PCR-DGGE). Results from all five studied sites showed that the diversity of AMF decreased with increasing Sb concentration. Principal component analysis (PCA) indicated that the AMF community structure was markedly different among these groups. Further redundancy analysis (RDA) showed that Sb contaminationwas the dominating factor influencing the AMF community structure in the Sb mine area. However, the multivariate analysis showed that, apart from the soil Sb content, extractable nitrogen content and organic matter content also attributed to AMF sequence distribution type. Some AMF sequences were only found in the highly contaminated area and these might be ideal candidates for improving phytoremediation efficiency in Sb mining regions. Gene sequencing analysis revealed that most species were affiliated with Glomus, suggesting that Glomus was the dominant AMF genus in the studied Sb mining area.     

The molecular diversity of arbuscular mycorrhizal fungi in the arsenic mining impacted sites in Hunan Province of China

Arbuscular mycorrhizal fungi(AMF) can establish a mutualistic association with most terrestrial plants even in heavy metal contaminated environments. It has been documented that high concentrations of toxic metals, such as arsenic(As) in soil could adversely affect the diversity and function of AMF. However, there are still gaps in understanding the community composition of AMF under long-term As contaminations. In the present study, six sampling sites with different As concentrations were selected in the Realgar mining area in Hunan Province of China. The AMF biodiversity in the rhizosphere soils of the dominant plant species was investigated by sequencing the nuclear small subunit ribosomal RNA(SSU rR NA) gene fragments using 454-pyrosequencing technique. A total of 11 AMF genera were identified,namely Rhizophagus, Glomus, Funneliformis, Acaulospora, Diversispora, Claroideoglomus, Scutellopora,Gigaspora, Ambispora, Praglomus, and Archaeospora, among which Glomus, Rhizophagus, and Claroideoglomus clarodeum were detected in all sampling sites, and Glomus was the dominant AMF genus in the Realgar mining area. Redundancy analysis indicated that soil pH, total As and Cd concentrations were the main factors influencing AMF community structure. There was a negative correlation between the AMF species richness and the total As concentration in the soil,but no significant correlation between the Shannon–Wiener index of the AMF and plants. Our study showed that high As concentrations can exert a selective effect on the AMF populations.     

黄土高原六道沟流域8种植物根际细菌与AMF群落多样性研究

采用末端限制性片段长度多态性(terminal restriction fragment length polymorphism,T-RFLP)方法,研究了神木县六道沟流域8种植物根际细菌与丛枝菌根真菌(arbuscular mycorrhizal fungi,AMF)群落多样性及其相互关系.目的是获得有关植物根际细菌和AMF群落的多样性指数,为生态环境修复提供科学依据.结果表明,8种植物根际细菌和AMF的种类和数量有较大差异,其中刺槐根际细菌的Shannon指数最高(4.01),垂柳最低(2.18),根际AMF的Shannon指数最高为小叶杨(2.07),最低为沙棘(1.21);聚类分析(cluster analysis)和冗余分析(redundancy analysis)结果表明,不同植物根际细菌和AMF的群落结构有较大差异,但同时部分植物间也存在相似性;8种植物根际细菌和AMF的多样性指数总体呈极显著的正相关(P<0.01);冗余分析结果表明在根际土壤环境因子中,对根际微生物群落多样性影响最大的环境因子为有机质含量.植物种类和根际环境对根际微生物群落结构有较大影响,同时,刺槐的根际细菌和AMF群落多样性指数均较高,故可作为六道沟流域植被恢复的先锋树种.