生物因子对AM真菌多样性的影响

丛枝菌根真菌(Arbuscular Mycorrhizas,AM）真菌分布于自然界各生态系统中,生态因子对AM真菌多样性个有举足轻重的影响,其中动物,植物,微生物,人为因素等生物因子的作用,亦日益受到人们的关注,通过介绍该领域最近10年来的研究成果,探讨和分析当前研究中所存在的问题和动向。     

我国东、南沿海地区AM真菌群落生态分布研究

在我国东、南沿海地区AM真菌资源调查的基础上研究了AM真菌的群落生态分布和特征。证明球囊霉属在该地区的出现频度和相对多度都最高,其次是硬囊霉属。该区内南四省AM真菌丰度、密度和物种多样性指数均比北三省高。聚类分析结果和上述相似,说明我国东、南沿海各省AM真菌的丰度、频度、密度、多度和多样性特征由北向南呈规律性变化。     

盐渍化土壤根际微生物群落及土壤因子对AM真菌的影响

为探明盐渍化土壤影响下AM真菌与根际土壤间的关系,试验选取宁夏碱化龟裂土、草甸盐土、盐化灌淤土3种类型4个样地上典型植被群落,测定了植物根际土壤养分含量、微生物群落结构、AM真菌侵染率以及孢子密度。结果显示:盐渍化土壤根际微生物碳源利用类型显著不同,对芳香类化合物的代谢能力整体较弱;红寺堡草甸盐土上微生物优势群落为氨基酸代谢类群,惠农盐化灌淤土为多聚化合物代谢群,西大滩碱化龟裂土为碳水化合物代谢群。AM真菌孢子密度与微生物碳源代谢群间的关系比较复杂。其中,惠农样点根际土壤孢子密度与多聚化合物微生物代谢群呈显著正相关,西大滩地区孢子密度与碳水化合物微生物代谢群呈显著正相关。土壤有机质、全盐、全氮、碱解氮等土壤肥力因子及土壤中的HCO-3、Na+、Cl-等盐基离子含量能解释AM真菌孢子密度与土壤环境因子之间相互关系的大部分信息。较高的HCO-3浓度促进了AM真菌侵染率的提高,但高盐浓度下Na+和Cl-降低了菌根侵染率。土壤对AM真菌孢子密度、侵染率的影响因土壤盐分组成类型的不同而异。研究结果为深入了解AM真菌多样性,促进宁夏盐碱地的合理开发与利用提供了理论依据。     

蒙古沙冬青根围AM和DSE真菌与土壤因子的相关性研究

于2012年6月对银川、沙坡头、民勤3个样地的蒙古沙冬青(Ammopiptanthus mongolicus)根围采集5个土层(0~10、10~20、20~30、30~40、40~50cm)的土样和根样,研究了蒙古沙冬青根际AM和DSE真菌空间分布以及土壤因子的生态作用,以阐明沙冬青与土壤真菌的共生关系,为利用共生真菌资源促进沙冬青生长和荒漠植被恢复提供依据。结果表明:(1)沙冬青根系能被AM和DSE真菌高度侵染,共生程度和生态分布具有明显空间异质性。(2)沙坡头样地AM真菌总定殖率最高,民勤DSE定殖率最高,但不同样地菌丝、泡囊、丛枝和定殖强度无显著差异;同一样地不同土层AM真菌总定殖率和DSE定殖率无显著差异。(3)相关性分析表明,AM真菌总定殖率与土壤速效P显著正相关;泡囊定殖率与有机质显著正相关,与速效P极显著正相关;定殖强度与总球囊霉素(TEG)显著正相关,与碱解N和速效K极显著正相关;DSE定殖率与易提取球囊霉素(EEG)极显著正相关,与碱解N显著正相关。(4)通径分析表明,土壤有机质、EEG和速效K是通过直接作用影响AM真菌总定殖率和DSE定殖率。     

不同土壤类型下甘蔗根系AM真菌多样性及与土壤因子关系

甘蔗是广西重要的糖料作物,本研究通过建立克隆文库、土壤养分分析和根样染色等方法测定了33个采样点3种土壤类型(赤红壤,红壤,砖红壤)下甘蔗根系AM真菌多样性及其与土壤因子的关系。结果表明,3种土壤类型的甘蔗根系共鉴定出6科6属11种AM真菌,AM真菌各属频度存在明显差异,其中球囊霉属的频度值最高,在33个根系样品中有32个存在该属,为广西甘蔗根系AM真菌的优势属,而类球囊霉属、无梗囊霉属、近明球囊霉属、多样孢囊霉属和盾巨孢囊霉属5个属为稀有属。3种土壤类型的甘蔗根系均发现有球囊霉属和盾巨孢囊霉属;近明球囊霉属、无梗囊霉属和类球囊霉属仅在赤红壤的甘蔗根系中出现;而多样孢囊霉属仅在在赤红壤和砖红壤的甘蔗根系中出现。土壤的pH与AM菌根侵染率呈显著正相关,而有机质、总N、有效P、交换性Mg2+与AM菌根侵染率均呈负相关。本研究表明,自然条件下甘蔗根系具有相对丰富的AM真菌类群,这些AM真菌可能在甘蔗生长过程中发挥着重要的生态功能。     

环境因子对AM真菌多样性的影响

土壤,气候和地理因子等环境因子对丝枝菌根（AM）真菌多样性有重要影响,本文系统地综述了最近10年来AM真菌生态学在该方面的最新研究成果,分析当前研究中所存在的问题和动向。     

AM真菌对黄瓜根围土壤微生物群落功能的影响

在温室土壤灭菌盆栽条件下对黄瓜(Cucumis sativus Linn.,"中农26号")接种丛枝菌根(arbuscular mycorrhizal,AM)真菌Funneliformis mosseae,测定了黄瓜根围土壤微生物功能、微生物数量以及土壤理化性质、土壤酶活性的变化。结果表明AM真菌可以提高土壤的速效养分含量,改善土壤物理性质,提高土壤中磷酸酶、氨肽基酶、多酚氧化酶及过氧化物酶活性;接菌处理后土壤中细菌、真菌数量显著高于不接种处理,而放线菌数量低于不接菌处理;对根围微生物功能多样性指标分析表明接菌处理的平均颜色变化率(AWCD)、Simpson优势度指数以及Mclntosh多样性指数,显著低于不接种对照。对菌根侵染率与土壤微生物等性状间的RDA分析表明AM真菌侵染率与速效P含量(r=0.65,P0.05)、磷酸酶(r=0.74,P0.05)、氨肽基酶(r=0.86,P0.05)、真菌数量(r=0.57,P0.05)呈正相关,与酚酸类碳源(r=-0.55,P0.05)、胺类碳源(r=-0.58,P0.05)、速效N(r=-0.77,P0.05)、β-葡糖苷酶(r=-0.90,P0.05)、β-纤维二糖苷酶(r=-0.63,P0.05)呈负相关。因此接种AM真菌的黄瓜菌根苗种植提高了土壤酶活性,优化了温室黄瓜根围微生物群落结构,显著改善了土壤理化性质。     

青岛胶州湾四种类型湿地AM真菌多样性

对青岛胶州湾4种类型湿地（盐田、滩涂、湖泊和河口）中芦苇Phragmites communis、香蒲Typha orientalis和碱蓬Suaeda glauca 根围土壤中丛枝菌根（arbuscular mycorrhizal,AM）真菌进行孢子分离与鉴定,分析湿地生态系统中植物根围AM真菌群落特征。共分离到AM真菌5属10种,包括斗管囊霉属Funneliformis 2种、无梗囊霉属Acaulospora 3种、近明球囊霉属Claroideoglomus 2种、球囊霉属Glomus 1种、巨孢囊霉属Gigaspora 2种,其中,斗管囊霉属Funneliformis及地斗管囊霉Funneliformis geosporum的分离频度和相对多度最高,分别为湿地中AM真菌优势属和优势种。滩涂和河口湿地中植物AM真菌侵染率显著高于湖泊和盐田湿地植物,AM真菌孢子密度以滩涂湿地最高（572个/20mL）,湖泊湿地最低（220个/20mL）;滩涂湿地的种丰度和Shannon-Wiener指数最高,分别为3.8和1.2。从植物种类来看,AM真菌侵染率总体呈现出香蒲>碱蓬>芦苇,AM真菌孢子密度以香蒲最高,芦苇最低,植物种类对AM真菌种丰度和Shannon-Wiener指数影响不显著（P>0.05）。二因素方差分析和典型RDA相关分析表明,寄主植物种类对AM真菌孢子密度有一定影响,但湿地类型对AM真菌多样性的影响更为显著（P<0.05）,胶州湾湿地土壤因子Ca ²⁺、速效P含量与AM真菌孢子密度、物种丰度和多样性指数显著负相关,而速效K、Na ⁺、pH与其显著正相关。结果表明植物种类主要影响AM真菌孢子密度,AM真菌多样性受植物种类和湿地类型综合影响,滩涂湿地较丰富的AM真菌多样性可能与该湿地较良好的理化性质有关。     

环境因子和AM真菌分布的关系

由我国东、南沿海七省２７８个土样中的９０８个ＡＭ真菌种次分析了ＡＭ真菌属和种的分布和７种环境因子的关系。球囊霉属在各种环境下均占绝对多数,巨囊霉属＋盾巨囊霉属则为最少,球囊霉属在各ｐＨ水平土壤中分布较均匀;而其它四属主要出现在ｐＨ低于７的土壤中,摩西球囊霉Ｃ．ｍｏｓｓｅａｅ（Ｎｏｃｏｌ．＆Ｇｅｒｄ）Ｇｅｒｄｅｍａｎｎ＆Ｔｒａｐｐｅ在ｐＨ低于５的土壤中仍能发现。所有五属ＡＭ真菌的出现率都随土壤有机质     

厦门市七种药用植物根围AM真菌的侵染率和多样性

调查了福建省厦门市7种常见药用植物根围丛枝菌根真菌分布情况、侵染率及其多样性。结果表明:7种药用植物均能与AM真菌形成良好的共生关系,且不同药用植物形成菌根的能力差异明显,盐肤木根围的孢子密度最高,29.0个/g土,喜树的侵染率最高,100%。含笑根围的孢子密度最低,4.7个/g土,鱼腥草的总侵染率最低,4.5%。共分离鉴定AM真菌4属63种,其中球囊霉属(Glomus)39种、无梗囊霉属(Acaulospora)18种、巨孢囊霉属(Gigaspora)4种、盾巨孢囊霉属(Scutellospora)2种,其中Glomus、Acaulospora为优势属,黑球囊霉G.melanosporum为优势种。盐肤木根围AM真菌种类最丰富,Shannon-Weiner指数H达到1.29。侵染率与各土壤因子均无显著相关;孢子密度与pH值极显著负相关;种的丰度与pH值显著负相关、与电导率极显著负相关、与孢子密度极显著正相关;Shannon-Weiner指数H与有机质极显著负相关;均匀度与有机质、孢子密度极显著负相关。厦门地区AM真菌资源十分丰富,多样性程度高,宿主植物不同,土壤因子对其侵染率、孢子密度、种的丰度、Shannon-Weiner指数、均匀度的影响也不同。为实现AM真菌生物技术应用于中药材规范化种植提供宝贵种质资源和理论依据。     

中国盐碱土壤中AM菌的生态分布

对我国盐碱土壤中丛枝菌根（Ａｒｂｕｓｃｕｌａｒ Ｍｙｃｏｒｒｈｉｚａ,ＡＭ） 菌的种属构成、生态分布状况进行了研究．结果表明,不同地区ＡＭ 菌种属构成不同,其种属组成、分布与土壤类型、碱化度和土壤有机质含量有关．盐渍化砂土、壤土和粘土中,Ｇｌｏｍｕｓ 属的真菌数量最多,Ａｃａｕｌｏｓｐｏｒａ 属次之,而Ｇｌｏｍｕｓ 属中的Ｇ．ｍｏｓｓｅａｅ 则是分布最为广泛的菌种．随土壤碱化度的增加,Ｇｌｏｍｕｓ ｍｏｓｓｅａｅ 出现频率随之相对增加．在一定范围内有机质含量越高,土壤中ＡＭ 菌种和属的种类就越多．ＡＭ 菌的种属组成因不同寄主植物而异,其中豆科植物根围中ＡＭ 菌分布的种属数量最多．     

荒漠沙柳根围AM真菌的空间分布

为探明荒漠植物沙柳(Salix psammophila)根围AM真菌空间分布和土壤因子生态作用,2009年5月在内蒙古黑城子、正蓝旗、元上都3个样地分别从0—10、10—20、20—30、30—40、40—50cm 5个土层采集沙柳根围土壤样品,系统研究了AM真菌空间分布及与土壤因子的相关性。结果表明,沙柳根围AM真菌平均孢子密度为108个?100g-1 土,平均定殖率61.7%;沙柳与AM真菌可形成良好的I型丛枝菌根。不同样地和采样深度对AM真菌孢子密度和定殖率有显著影响,最大孢子密度和最高定殖率均出现在0—10cm土层,并随土层深度增加而下降。黑城子样地孢子密度显著高于其它样地。沙柳根围土壤总球囊霉素(TEG)和易提取球囊霉素(EEG)含量在3个样地均随土层加深而降低,平均值分别为0.24mg?g-1和 0.16mg?g-1,占土壤有机C 23.6%—24.6% 和14.9%—17.3%。相关分析表明,土壤速效P、碱解N与孢子密度显著负相关;土壤有机C与菌丝定殖率显著正相关,与泡囊定殖率显著负相关;土壤磷酸酶与孢子密度和侵染强度极显著正相关;土壤脲酶与孢子密度和定殖率极显著正相关;土壤总球囊霉素和易提取球囊霉素与土壤有机C极显著正相关。主成分分析表明,土壤有机C、磷酸酶和碱解N是影响荒漠土壤AM真菌分布和活动的主要因子。上述结果对进一步探明宿主植物、菌根和土壤三者之间的内在联系,充分利用AM真菌资源,促进荒漠植被恢复和生态重建具有重要意义。     

Effect of arbuscular mycorrhizal fungi, organic fertilizer and soil sterilization on maize growth

The effects of inoculation with arbuscular mycorrhizal (AM) fungi, organic fertilizer (F) applications, and soil sterilization on maize growth were evaluated in a pot experiment. The experiment was in a completely randomized factorial design (2 × 4 × 2) with six replicates for each treatment. There were two soil treatments (sterilized soil, SS and unsterilized soil, US), four organic fertilizer treatments (0.0, 0.5, 1.0 and 2.0 g kg^?1 soil), and two AM fungi treatments (inoculation with Glomus mosseae, +AM and uninoculated control, ?AM). Inoculated plants generally had greater AM colonization, plant height, dry weight and phosphorus (P) uptake than uninoculated controls, and these parameters were significantly increased as the organic fertilizer application increased up to 0.5 g kg^?1 but decreased or had no significant effect compared to the uninoculated plants at the highest fertilizer rate (2.0 g kg^?1). Plant growth, P uptake and AM colonization of root system were significantly higher in sterilized soil compared to the unsterilized control. Our results indicated that the inoculation of AM fungi in field soil with optimal organic fertilizer application greatly improved maize growth and nutrient uptake, and the effect was greater under sterilized soil condition.     

Effect of arbuscular mycorrhizal fungi, organic fertilizer and soil sterilization on maize growth ☆

The effects of inoculation with arbuscular mycorrhizal (AM) fungi, organic fertilizer (F) applications, and soil sterilization on maize growth were evaluated in a pot experiment. The experiment was in a completely randomized factorial design (2 × 4 × 2) with six replicates for each treatment. There were two soil treatments (sterilized soil, SS and unsterilized soil, US), four organic fertilizer treatments (0.0, 0.5, 1.0 and 2.0 g kg^-1 soil), and two AM fungi treatments (inoculation with Glomus mosseae, +AM and uninoculated control, －AM). Inoculated plants generally had greater AM colonization, plant height, dry weight and phosphorus (P) uptake than uninoculated controls, and these parameters were significantly increased as the organic fertilizer application increased up to 0.5 g kg^-1 but decreased or had no significant effect compared to the uninoculated plants at the highest fertilizer rate (2.0 g kg^-1). Plant growth, P uptake and AM colonization of root system were significantly higher in sterilized soil compared to the unsterilized control. Our results indicated that the inoculation of AM fungi in field soil with optimal organic fertilizer application greatly improved maize growth and nutrient uptake, and the effect was greater under sterilized soil condition.     

Large contribution of arbuscular mycorrhizal fungi to soil carbon pools in tropical forest soils

The origins and composition of soil organic matter (SOM) are still largely uncertain. Arbuscular mycorrhizal fungi (AMF) are recognized as indirect contributors through their influence on soil aggregation, plant physiology, and plant community composition. Here we present evidence that AMF can also make large, direct contributions to SOM. Glomalin, a recently discovered glycoprotein produced by AMF hyphae, was detected in tropical soils in concentrations of over 60 mg cm^–3. Along a chronosequence of soils spanning ages from 300 to 4.1 Mio years, a pattern of glomalin concentrations is consistent with the hypothesis that this protein accumulates in soil. Carbon dating of glomalin indicated turnover at time scales of several years to decades, much longer than the turnover of AMF hyphae (which is assumed to be on the order of days to weeks). This suggests that contributions of mycorrhizae to soil carbon storage based on hyphal biomass in soil and roots may be an underestimate. The amount of C and N in glomalin represented a sizeable amount (ca. 4–5%) of total soil C and N in the oldest soils. Our results thus indicate that microbial (fungal) carbon that is not derived from above- or below-ground litter can make a significant contribution to soil carbon and nitrogen pools and can far exceed the contributions of soil microbial biomass (ranging from 0.08 to 0.2% of total C for the oldest soils).     

Interactions between arbuscular mycorrhizal fungi and soil bacteria

The soil environment is interesting and complicated. There are so many interactions taking place in the soil, which determine the properties of soil as a medium for the growth and activities of plants and soil microorganisms. The soil fungi, arbuscular mycorrhiza (AM), are in mutual and beneficial symbiosis with most of the terrestrial plants. AM fungi are continuously interactive with a wide range of soil microorganisms including nonbacterial soil microorganisms, plant growth promoting rhizobacteria, mycorrhiza helper bacteria and deleterious bacteria. Their interactions can have important implications in agriculture. There are some interesting interactions between the AM fungi and soil bacteria including the binding of soil bacteria to the fungal spore, the injection of molecules by bacteria into the fungal spore, the production of volatiles by bacteria and the degradation of fungal cellular wall. Such mechanisms can affect the expression of genes in AM fungi and hence their performance and ecosystem productivity. Hence, consideration of such interactive behavior is of significance. In this review, some of the most important findings regarding the interactions between AM fungi and soil bacteria with some new insights for future research are presented.     

内蒙古荒漠沙柳AM真菌物种多样性

分别于2009年5月、8月和10月在内蒙古黑城子、正蓝旗和元上都3个样地采集沙柳(Salix psammophila)根围0-50 cm土层土样,研究了AM真菌群落组成及其生态分布特点.在分离的4属37种AM真菌中,球囊霉属(Glomus)23种,无梗囊霉属(Acaulospora)10种,这两属是3样地共同优势属;盾巨孢囊霉属(Scutellospora)3种,仅分布在黑城子和正蓝旗样地;巨孢囊霉属(Gigaspora)1种,仪分布在正蓝旗样地;网状球囊霉(G.reticulatum)是3样地共同优势种.AM真菌种丰度、均匀度指数、Shannon多样性指数、Simpson多样性指数大小依次是正蓝旗>黑城子>元上都;元上都样地的AM真菌组成与其他样地差异显著;8月和10月的AM真菌种丰度、Shannon多样性指数显著高于5月.随土壤碱解N含量提高,AM真菌种丰度、均匀度指数、物种多样性指数先升后降.结果提示,在评估荒漠环境沙柳和AM真菌共生关系时,AM真菌生态分布和丰富度是十分有用的指标.     

内蒙古露天煤矿区回填土壤具生态适应能力丛枝菌根真菌的筛选

在盆栽试验条件下,应用灭菌的露天煤矿区回填土壤为培养基质,研究8个丛枝菌根真菌菌种(株)对沙打旺生长及根系侵染的影响.结果表明,分离自江西和新疆的Glomus mosseae的2个菌株在露天煤矿区回填土壤上能够显著提高沙打旺的生物量,并能有效改善植株的磷、氮营养;其侵染率均在50%以上,且根外繁殖体数显著高于其他接种处理.说明此两个菌株在该土壤上具有良好的生态适应能力,有助于露天煤矿区植被重建和生态恢复等研究工作的进一步开展.     

Molecular biodiversity of arbuscular mycorrhizal fungi in trace metal-polluted soils

We assessed the indigenous arbuscular mycorrhizal fungi (AMF) community structure from the roots and associated soil of Plantago major (plantain) plants growing on sites polluted with trace metals (TM) and on unpolluted sites. Uncontaminated and TM-contaminated sites containing As, Cd, Cu, Pb, Sn and Zn were selected based on a survey of the TM concentration in soils of community gardens in the City of Montréal. Total genomic DNA was extracted directly from these samples. PCR followed by denaturing gradient gel electrophoresis (PCR-DGGE), augmented by cloning and sequencing, as well as direct sequencing techniques, was all used to investigate AMF community structure. We found a decreased diversity of native AMF (assessed by the number of AMF ribotypes) in soils and plant roots harvested from TM-polluted soils compared with unpolluted soils. We also found that community structure was modified by TM contamination. Various species of Glomus, Scutellospora aurigloba and S. calospora were the most abundant ribotypes detected in unpolluted soil; ribotypes of G. etunicatum, G. irregulare/G. intraradices and G. viscosum were found in both polluted and unpolluted soils, while ribotypes of G. mosseae and Glomus spp. (B9 and B13) were dominant in TM-polluted soils. The predominance of G. mosseae in metal-polluted sites suggests the tolerance of this species to TM stress, as well as its potential use for phytoremediation. These data are relevant for our understanding of how AMF microbial communities respond to natural environments that contain a broad variety of toxic inorganic compounds and will substantially expand our knowledge of AMF ecology and biodiversity.