丛枝菌根（AM）真菌对翅果油树幼苗根系的影响

采用接种和不接种(对照)丛枝菌根的方法对翅果油树幼苗在不同生长时期的形态、生物量、矿质元素含量及抗逆性等指标进行比较分析,以探讨丛枝菌根(AM)改善翅果油树在生态系统中的退化及濒危现状的机理.结果显示:(1)摩西球囊霉(Glomus mosseae)和脆无梗囊霉(Acaulospora delicata)与盆栽翅果油树苗木可形成菌根;菌根化苗木的形态及生物量等指标均与对照差异极显著,且与菌根侵染率呈显著正相关(P<0.05).(2)菌根使苗木根系体积增大、总吸收面积增加、根系的活跃吸收面积显著增加,且根系中活跃吸收面积比与磷、钾元素含量呈显著正相关(P<0.05).(3)苗木生长的盛期和末期,菌根化苗木根系过氧化物酶活性显著高于对照,而在生长后期却显著低于对照呈负相关(P<0.05);菌根化苗木根系多酚氧化酶活性显著高于对照(P<0.05),在苗木生长盛期酶活性最强,但接种不同菌种的苗木间差异不显著.研究表明,与不接种相比,接种菌根增加了翅果油树的根系吸收能力,提高了根系酶体系,有利于植物抵抗各种胁迫,对扩大翅果油树植物的分布区有重要意义.     

云南热带蕨类植物根际土壤中的六种VA菌根真菌

从热带地区野生或从野外移栽于温室中的蕨类植物根际土壤中分离得到六种ＶＡ菌根真菌：双网无梗囊霉Ａｃａｕｌｏｓｐｏｒａ ｂｉｒｅｔｉｃｕｌａｔａ Ｒｏｔｈｗｅｌｌ ｅｔ Ｔｒａｐｐｅ,细凹无梗囊霉Ａｃａｕｌｏｓｐｏｒａ ｓｃｒｏｂｉｃｕｌａｔａ Ｔｒａｐｐｅ,瘤状无梗囊霉Ａｃａｕｌｏｓｐｏｒａ ｔｕｂｅｒｃｕｌａｔａ Ｊａｎｏｓ ＆ Ｔｒａｐｐｅ,多梗球囊霉Ｇｌｏｍｕｓ ｍｕｌｔｉｃａｕｌｅ Ｇｅｒｄ     

溶磷细菌和丛枝菌根真菌接种对南方红豆杉生长及根际微生物和土壤酶活性的影响

以南方红豆杉实生苗为材料,采用盆栽实验探讨了高效溶磷细菌草木樨中华根瘤菌(Sinorhizobium meliloti)CHW10B与丛枝菌根真菌缩球囊霉(Glomus constrictum)单独和双接种条件下,其植株生长、根际土壤可培养微生物数量、土壤酶活和土壤微生物功能多样性变化,在微生态水平揭示接种对南方红豆杉生长的影响及其机制。结果表明:(1)各接种处理对南方红豆杉幼苗均有促生长作用,接种处理苗高、地径和生物量均较对照显著增加,并以双接种促进效果最好。(2)各接种处理提高了南方红豆杉根际土壤可培养细菌、真菌和放线菌含量,增加了土壤微生物碳源利用率,改变了土壤中物种的丰富度和均一度,增加了土壤中的生物多样性。(3)各接种处理促进了南方红豆杉根际重要土壤酶(酸性磷酸酶、脱氢酶、转化酶)活力的增加,且双接种的促进作用最为明显。可见,溶磷细菌(草木樨中华根瘤菌CHW10B)和丛枝菌根真菌(缩球囊霉)具有协同作用,两者同时接种可显著提高南方红豆杉根际土壤微生物数量及土壤酶活力,提高土壤微生物碳源利用率和土壤肥力,增加土壤中的生物多样性,从而达到间接促进宿主植物南方红豆杉生长的目的。     

丛枝菌根对植物根际逆境的生态学意义

近年来,我国在菌根分子生物学、菌根营养学、菌根分类学和菌根生态学等方面取得了令人瞩目的研究成果,其中对丛枝菌根真菌(AMF)的研究居多。AMF能与大部分陆地植物根系形成共生关系,促进植物生长发育,提高植物抗逆性,在保持生态平衡、保护生态环境等方面发挥重要作用。本文主要从非生物胁迫(干旱胁迫、重金属污染、盐碱胁迫)和生物胁迫(致病菌和线虫侵染)方面介绍了AMF在植物根际逆境中发挥的生态功能及作用机制,提出了该研究领域尚存的不足之处和研究前景,为AMF后续研究提供参考。     

植物根际促生菌及丛枝菌根真菌协助植物修复重金属污染土壤的机制

植物修复是一种前景广阔的重金属污染土壤的主要修复技术,在微生物的协助下效果更为显著。植物根际促生菌可通过分泌吲哚-3-乙酸(IAA)、产铁载体、固氮溶磷等方式促进植物生长、改善植物重金属耐受性,从而有效提高重金属污染土壤的植物修复效率。菌根真菌是土壤-植物系统中重要的功能菌群之一,可侵染植物根系改变根系形态和矿质营养状况,通过菌丝体吸附重金属,也可产生球囊霉素、有机酸、植物生长素等次生代谢产物改变重金属生物有效性。植物根际促生菌与丛枝菌根真菌可对植物产生协同促生作用,在重金属污染土壤修复中具有一定应用潜力。目前,国内外关于植物根际促生菌和丛枝菌根真菌互作已有大量研究,而二者的相互作用机理仍处于探索阶段。本文综述了近年来国内外植物根际促生菌和丛枝菌根真菌在重金属污染土壤植物修复中的作用机制,并对其研究前景进行展望。     

间作作物种间相互作用对马铃薯根际土壤丛枝菌根真菌的影响

为揭示间作作物种间相互作用对土壤丛枝菌根(AM)真菌的影响,以马铃薯单作(T0)为对照,基于高通量测序平台的方法,研究了连续3年马铃薯‖玉米(T1)、马铃薯‖蚕豆(T2)下马铃薯根际土壤AM真菌群落组成、多样性与土壤环境因子间的相互关系.结果表明:共获得2893个AM真菌操作分类单元(OTUs),分属1门、3纲、4目、...     

丛枝菌根真菌参与下植物-土壤系统的养分交流及调控

近几年随着有机农业的发展,丛枝菌根的作用受到特别关注。丛枝菌根是由植物根系与丛枝菌根真菌(AMF)形成的一种共生体。在植物-AMF-土壤系统中,AMF为植物提供N、P等营养的同时从根系得到所需的C。概述了植物-AMF-土壤系统中C、N、P等营养物质的交流以及AMF与土壤微生物的互作关系。丛枝菌根的形成可显著提高植物对P的吸收,且在高P条件下多余的P可储存于AMF中。AMF对土壤N循环的影响相当复杂,可能参与调控N循环的多个过程,如硝化作用、反硝化作用和氨氧化作用等。在有机质丰富的土壤中AMF菌丝可快速扩增并吸收其中的N,主要供菌丝自身所需,只有一小部分传递给植物。AMF对土壤C库的影响尚存争议,可能存在时间尺度的差异。短期内可活化土壤C,而在长期尺度上可能有利于土壤C的储存。AMF能够通过改变土壤微生物群落结构而影响植物-土壤体系的物质交流。AMF与解磷菌、根瘤菌和放线菌的协同增效作用可促进土壤有机质的降解或增强其固氮能力;AMF对氨氧化菌的抑制作用可降低氨的氧化减少N2O的释放。AMF与外生共生真菌EMF共存时,表现出协同增效作用,但EMF的优先定殖会限制AMF的侵染。AMF不同类群之间则主要表现为竞争和拮抗关系。AMF与土壤微生物之间的互作关系受土壤无机环境的影响,在养分亏缺条件下微生物之间往往表现为竞争关系。因植物、AMF与土壤微生物之间存在复杂的互作关系,为此AMF并不总是表现出其对植物营养的促进作用。目前关于AMF的作用机理仍以假说为主,需要进一步的实验验证。在植物-AMF-土壤系统中N与C的交流和P与C的交流并未表现出一致性,对N、P循环相互关系的进一步探讨有助于深入理解植物-土壤体系中的养分循环。植物、AMF和土壤微生物的养分来源及其对养分的相对需求强度和吸收效率尚未可知,因此无法深入理解AMF在植物-土壤体系中养分交流和转化的作用。在方法上,传统的土壤学方法在养分动态研究中存在局限性,现代分子生物学手段和化学计量学的结合值得尝试。     

大气二氧化碳浓度升高对植物根际微生物及菌根共生体的影响

综述了大气CO2浓度升高条件下,植物根际土壤环境、根际土壤微生物和植物菌根形成的变化趋势等方面的研究进展,CO2浓度升高,运转到根系的碳水化合物增加,根际环境、根际微生物活性、微生物群落结构以及菌根共生体的形成发生变化．提出在CO2浓度升高条件下,根际微生物和菌根真菌群落的变化对植物群落和陆地生态系统碳动态的调节是今后的研究趋向。     

亚精胺和丛枝菌根真菌对黄瓜生长的影响

以黄瓜品种‘津春2号’为材料,在育苗基质中添加亚精胺(Spd)和丛枝菌根真菌(AMF),研究外源Spd和AMF对黄瓜幼苗生长、光合作用、果实产量和品质以及根际微生物和酶活性的影响.结果表明:育苗基质中同时添加Spd和AMF,可促进黄瓜幼苗生长,提高根系活力和果实产量,改善品质,并促进养分吸收;Spd和AMF提高黄瓜幼苗净光合速率、实际光化学效率、表观量子效率、羧化效率和光呼吸速率,增加基质中细菌和放线菌数量,而降低真菌数量,并提高蔗糖酶、中性磷酸酶、过氧化氢酶和脲酶的活性.说明育苗基质中同时添加Spd和AMF,可提高黄瓜植株光能利用效率,促使黄瓜幼苗根际微生物区系从低肥力的"真菌型"向高肥力的"细菌型"转化,加速有机磷和有机态氮的分解与转化,为黄瓜生长发育提供比较充足的N、P等养分,从而促进黄瓜植株生长,提高产量并改善品质.Spd可提高AMF侵染率,两者对黄瓜幼苗生长具有明显的叠加效应,说明在接种AMF的基质中添加Spd,是一种可增强AMF侵染率的有效方法.     

丛枝菌根真菌对连翘幼苗抗旱性的影响

采用集球囊霉（Glomus fasciculatum Gerd.＆ Trappe emend.Walker ＆ Koske）、缩球囊霉（Glomus constrictum Trappe）单独接种和混合接种于连翘（Forsythia suspensa（Thunb.）Vahl）幼苗,研究丛枝菌根真菌对连翘抗旱性的影响.结果表明：在干旱胁迫条件下,随着菌根侵染率的提高,连翘幼苗叶绿素和脯氨酸含量增加,SOD活性增强,丙二醛含量和膜透性降低,苗木枯死率下降.菌根真菌通过促进苗木快速累积游离脯氨酸,提高SOD酶活性,减缓干旱对细胞膜的破坏,延缓了植物受伤害的速度,提高连翘幼苗的抗旱性;在不同接种处理间,混合接种效果最好,其次为缩球囊霉单独接种.     

翅果油树幼苗抗旱性

通过盆栽试验,研究不同土壤水分条件下翅果油树（Elaeagnus mollis）幼苗的生长、叶水分和丙二醛含量等各项生理指标的变化。结果表明,轻、中度干旱（30％～35％、45％～50％）胁迫时叶片含水量和叶绿素含量下降幅度较小,水势较高,丙二醛含量较低,翅果油树幼苗能保汪基本的生长,表现出耐旱植物的生理特征;在重度干旱胁迫（20％～25％）条件下,叶含水量和叶绿素含量下降较显著,水势最低,丙二醛含量最高,植株矮小,颜色发黄,表明翅果油树幼苗受到干旱伤害严重,不能正常生长。     

Depletion of soil mineral N by roots of Cucumis sativus L. colonized or not by arbuscular mycorrhizal fungi

Two experiments were conducted where Cucumis sativus were grown in uncompartmented pots either alone or in symbiosis with Glomus intraradices Schenck and Smith (Experiment 1) or Glomus sp. (Experiment 2) in order to investigate if root colonization by arbuscular mycorrhizal (AM) fungi has an effect on depletion of the soil mineral N pool. All pots were gradually supplied with 31 mg NH₄NO₃-N kg^-1 dry soil from 12–19 days after planting and an additional 50 mg (NH₄)₂SO₄-N kg^-1 dry soil (¹⁵N-labelled in Experiment 1) was supplied at 21 or 22 days after planting in Experiments 1 and 2, respectively. Dry weight of plant parts, total root length, mycorrhizal colonization rate and soil concentration of NH ₄ ⁺ and NO ₃ ^- were recorded at five sequential harvest events: 21, 24, 30, 35 and 42 days (Experiment 1) and 22, 25, 28, 31 and 35 days (Experiment 2) after planting. In Experiment 1, plants were also analysed for total content of N and ¹⁵N. The mycorrhizal colonization rate increased during time: from 25 to 40% in Experiment 1 and from 50 to 60% in Experiment 2. Plant dry matter accumulation was unaffected by mycorrhizal colonization, except in Experiment 1 where shoot dry weights were slightly increased and in Experiment 2 where root dry weights were slightly decreased compared to non-mycorrhizal control plants. The total root length was similar in the control and mycorrhizal treatments in Experiment 1, while it was decreased (20–30%) by mycorrhizal colonization in the last two harvest in Experiment 2. Mycorrhizal colonization affected the rate of depletion of soil mineral N in Experiment 1, where both NH ₄ ⁺ and NO ₃ ^- concentrations were markedly lower in the first two harvests, when plants were mycorrhizal. As the root length was similar in mycorrhizal and control treatments, this may indicate that the external AM hyphae contributed to the depletion of the soil mineral N pool. A similar pattern was observed in Experiment 2, although the effect was less pronounced. The ¹⁵N enrichment in mycorrhizal plants (Experiment 1) also indicated a faster NH ₄ ⁺ uptake than in the non-mycorrhizal controls in the first two harvests after application of the ¹⁵N-labelled N source. However, the external hyphae and roots seemed to have access to the same N sources as the ¹⁵N enrichment and total N content were similar in mycorrhizal and control plants at the end of the experiment. This revised version was published online in June 2006 with corrections to the Cover Date.     

Influence of arbuscular mycorrhizal fungi on soil structure and aggregate stability of a vertisol

The influence of arbuscular mycorrhizal (AM) fungi on aggregate stability of a semi-arid Indian vertisol was studied in a pot experiment in which Sorghum bicolor (L.) was grown as test plant for 10 weeks. Pasteurized soil inoculated with AM fungi was studied with pasteurized and unpasteurized soils as references. A part of the soil in each pot was placed in nylon mesh bags to separate effects of roots and hyphae. The sorghum plants were planted outside the mesh bags which permitted AM hyphae to enter while excluding roots. Aggregate stability of the soil was determined by wet-sieving and turbidimetric measurements. Development of the AM fungi was quantified as colonized root length and external hyphal length. Soil exposed to growth of roots and hyphae (outside mesh bags) showed aggregates with larger geometric mean diameter (GMD) in pasteurized soil inoculated with AM fungi than in pasteurized uninoculated soil. There was no significant difference in GMD of the inoculated, pasteurized soil and the unpasteurized soil. No significant effects of inoculation or plant growth were found in pasteurized soil exposed to hyphal growth only (inside the mesh bags). However, the unpasteurized soil had significantly higher GMD than the pasteurized soil, irrespective of plants and inoculum. Turbidimetric measurements of soil exposed to roots and hyphae (outside mesh bags) showed the highest aggregate stability for the inoculated pasteurized soil. These results demonstrate that AM fungi contribute to the stabilization of soil aggregates in a vertisol, and that the effect is significant after only one growing season. The effect was associated with both AM hyphae and the stimulation of root growth by AM fungi. The contribution from plant roots and AM hyphae to aggregate stability of different size fractions is discussed. This revised version was published online in August 2006 with corrections to the Cover Date.     

丛枝菌根真菌在土壤氮素循环中的作用

作为植物需求量最大的营养元素,氮素是陆地生态系统初级生产力的主要限制因子。丛枝菌根真菌能与地球上80%以上的陆生植物形成菌根共生体,帮助宿主植物吸收土壤中的P、N等矿质养分。目前,丛枝菌根真菌与氮素循环相关研究侧重于真菌对氮素的吸收形态以及共生体中氮的传输代谢机制,却忽略了丛枝菌根真菌在固氮过程、矿化与吸收过程、硝化过程、反硝化过程以及氮素淋洗过程等土壤氮素循环过程中所起到的潜在作用,并且越来越多的证据也表明丛枝菌根真菌是影响土壤氮素循环过程的重要因子。总结了丛枝菌根真菌可利用的氮素形态及真菌的氮代谢转运相关基因的研究现状;重点分析了丛枝菌根真菌在调控土壤氮素循环过程中的潜在作用以及在生态系统中的重要生态学意义,同时提出了丛枝菌根真菌在土壤氮素循环过程中一些需要深入研究的问题。     

Influence of arbuscular mycorrhizal fungi on soil structure and soil water characteristics of vertisols

The influence of inoculation with arbuscular mycorrhizal fungi (AM fungi) on soil water characteristics of fast and slowly wetted vertisol samples was studied. Vertisols characteristically have a low stability to wetting, and the disruption of their larger pores when they swell leads to reduced water infiltration and thereby to runoff. The degree of aggregate breakdown determines the ability of the soil to drain. A vertisol was used in this pot experiment with four treatments: T₁: Pasteurized soil, T₃: Pasteurized soil, with plants, T₄: Inoculated, pasteurized soil, with plants, T₅: Unpasteurized soil, with plants. A treatment using inoculated, pasteurized soil (T₂) was included in a related study (Bearden and Petersen, 2000) comparing aggregate stability, and the present study follows the same numbering to aid in comparison of experiments. After fast, disruptive wetting, the soil inoculated with AM fungi (T₄) was found to have a lower soil water content than did the soils from the other treatments at matric potentials lower than –3.92 kPa. This indicates greater drainage from pores smaller than 75 m for the soil inoculated with AM fungi, and the greater drainage appears to be directly related to a characteristic pore range between 67 and 75 m. The soil without plants (T₁), when wetted fast, had a lower soil water content at matric potentials higher than –3.92 kPa than soils from the other treatments, which indicates less pore volume due to pores larger than 75 m in the treatment without plants. The pore indexes, calculated as the ratio between the slope of the fast and the slope of the slowly-wetted water characteristics, generally had the highest values for the soil inoculated with AM fungi (T₄) from matric potential 0.00 to –0.29 kPa. In this matric potential range, the pore indexes were less than one. The unpasteurized soil with naturally present AM fungi (T₅) generally had the highest pore indexes from matric potential –0.49 to –3.92 kPa, and the pore indexes in this matric potential range were above one. These results indicate the smallest loss of very large pores in the soil inoculated with AM fungi (T₄) and the largest gain of smaller sized pores in the unpasteurized soil (T₅). This suggests that the resistance to breakdown of the largest pores is related to the presence of roots, and that the gain of groups of smaller pores is related to the presence of hyphae.     

AMF和PGPR联合修复菲和芘污染土壤的效应

丛枝菌根真菌（arbuscular mycorrhizal fungi,AMF）与根围促生细菌（plant growth-promoting rhizobacteria,PGPR）联合降解有毒有机物、修复污染土壤和促进植物生长的作用倍受关注。本试验旨在探究AMF与PGPR联合降解土壤中菲和芘的效应,以菲和芘1:1混合处理浓度各0、50mg/kg、100mg/kg和150mg/kg下对高羊茅Festuca elata接种AMF根内根孢囊霉Rhizophagus intraradices（Ri）、变形球囊霉Glomus versiforme（Gv）、PGPR荧光假单胞菌Pseudomonas fluorescens Ps2-6、芽孢杆菌Bacillus velezensis Ps3-2、Ri+Ps2-6、Ri+Ps3-2、Gv+Ps2-6、Gv+Ps3-2和不接种对照共36个处理。结果表明,供试AMF增加了PGPR的定殖数量;接种PGPR则显著提高AMF的侵染率。AMF、PGPR或AMF+PGPR处理均显著降低土壤中菲和芘含量,促进植物对土壤中菲和芘的吸收,显著提高高羊茅根系和叶片内的菲和芘含量。在土壤中菲和芘100mg/kg和150mg/kg水平下,Gv与Ps2-6及Ri与Ps2-6能相互促进对土壤中菲和芘的去除效应,其中接种Gv+Ps2-6组合处理的去除率最高,达到95%-98%,土壤中多酚氧化酶、脱氢酶和过氧化氢酶活性显著高于单接种处理和不接种对照,而酸性磷酸酶活性变化则表现为相反趋势。其中以Gv+Ps2-6组合处理的多酚氧化酶活性最高,为0.17mg/g,是不接种对照的1.9倍;脱氢酶和过氧化氢酶活性分别达到1.32µg/(g·h)和1.81mL/g;酸性磷酸酶活性则比不接种对照土壤降低27%-45%;易提取球囊霉素相关土壤蛋白含量和总球囊霉素相关土壤蛋白含量分别是不接种对照的1.6倍和1.5倍。     

Growth of micropropagated bananas colonized by root-organ culture produced arbuscular mycorrhizal fungi entrapped in Ca- alginate beads

The effect of root-organ culture (ROC) produced arbuscular mycorrhizal fungi (AMF), i.e. Glomus proliferum, Glomus versiforme and Glomus intraradices, entrapped in Ca-alginate beads on the first stages development of micropropagated bananas (Musa spp. cv. Grande Naine) was investigated. The experimental design consisted of banana plants inoculated with one of the three AMF and two controls, i.e. Control-AL (with empty alginate beads), and Control (no beads). Forty plants were considered per treatment and cultured under greenhouse conditions in a completely randomized design. Eight plants per treatment were harvested 40, 80, 120, 160 and 200 days after inoculation and analysed for root colonization, growth parameters and nutrient concentration. In addition, spores were enumerated in the substrate at the same intervals. Ca-alginate entrapped ROC-produced AMF spores were able (1) to colonize the root system of a micropropagated banana cultivar under nursery conditions, (2) to increase plant P nutrition and biomass, and (3) to proliferate in the commercial nursery substrate, therefore increasing the fungal inoculum biomass. The entrapment of ROC-propagated spores, adaptable to a wide range of Glomeromycetes, represents thus a forthcoming alternative pathogen-free inoculum.     

Interaction of soil microbes with mycorrhizal fungi in tomato

In this study, the interaction of soil microbes with mycorrhizal fungi (MF) was performed to understand the effect on tomato. A pot and a field experiment were employed to investigate the impact of soil microbes i.e. Fusarium oxysporum f. sp. lycopersici, Trichoderma harzianum, Aspergillus niger and Rhizobium leguminosarum, on AM fungi in pots and field studies. The soils without microbes which treated controls with or without mycorrhizal inoculation were also included. Plant growth and root colonisation were measured 36, 75 and 120?days post inoculation (dpi) in the both pot experiment and field study. Soil microbes’ effects on the growth behaviour of the tomato plant were determined via the shoot and root weight. R. leguminosarum and A. niger did not affect the colonisation ability much, but F. oxysporum f. sp. lycopersici and T. harzianum resulted in the inhibition of AM fungal colonisation in both pot and field studies. Our study provides evidence for the effects of soil microbes on the diversity of AM fungi and their effect on the tomato plants. The higher concentrations of phosphorus and of proteins in the root tissues, previously colonised with AM fungi, point out their effect as biofertilizers, according to the concept of sustainable agriculture.