丛枝菌根(AM)对根瘤菌趋化作用研究

对紫穗槐非接种(AM-+Rh-)、单接种根瘤菌(Rh+)、单接种AM真菌(AM+)和双接种(AM++Rh+)处理, 研究AM真菌、根瘤菌对宿主植物紫穗槐侵染情况, 并采用经过改良的根部微生物趋化试验手段研究AM真菌侵染根系后分泌物对根瘤菌的趋化性。实验结果表明：在接种AM++ Rh+情况下, 使宿主先于AM+、Rh+处理形成根瘤, 且双接种能够显著提高菌根侵染率; 在共生体形成期间, AM真菌与根瘤菌之间存在着识别互动反应和一定的信号物质, 接种AM真菌对根瘤菌有正趋化作用; 同时, 外界温度对AM真菌-宿主植物---根瘤菌三者共生体初始信号识别也起到一定的调控作用。     

四种蕨类植物根际土壤中VA菌根真菌孢子种群组成和季相变化

对４ 种移栽到温室中的蕨类植物根际土壤中的ＶＡ 菌根真菌孢子种群组成和季相变化进行了研究, 结果发现, ＶＡ菌根真菌孢子的产生具有明显的宿主依赖性和季相变化。在相同气候条件下, 不同植物根际土壤中的ＶＡ菌根真菌种群组成不同; 同种ＶＡ 菌根真菌在不同宿主植物根际土壤中, 孢子的丰富度有很大的差异。本文对影响ＶＡ菌根真菌孢子种群组成和季相变化的因素进行了讨论。     

丛枝菌根(AM)对根瘤菌趋化作用研究

对紫穗槐非接种(AM- Rh-)、单接种根瘤菌(Rh )、单接种AM真菌(AM )和双接种(AM Rh )处理,研究AM真菌、根瘤茵对宿主植物紫穗槐侵染情况,并采用经过改良的根部微生物趋化试验手段研究AM真菌侵染根系后分泌物对根瘤茵的趋化性.实验结果表明:在接种AM Rh 情况下,使宿主先于AM ,Rh '处理形成根瘤,且双接种能够显著提高菌根侵染率;在共生体形成期间,AM真菌与根瘤菌之间存在着识别互动反应和一定的信号物质,接种AM真菌对根瘤菌有正趋化作用;同时,外界温度对AM真菌.宿主植物一根瘤茵三者共生体初始信号识别也起到一定的调控作用.     

菌根真菌与植物共生营养交换机制研究进展

菌根是陆地生态系统普遍存在的、由土壤中的菌根真菌侵染宿主植物根系形成的联合共生体.菌根的建立是以共生体双方的营养交换为基础的:菌根真菌从土壤中吸收氮、磷等营养物质并转运给宿主植物,供其生长;作为交换,植物则以脂质或糖的形式向菌根真菌提供其生长所必需的碳水化合物.近年来,菌根真菌与宿主植物间的营养交换机制一直是研究的热点,国内外对菌根真菌介导的植物营养物质吸收和转运机制的研究也取得了巨大进展.本文综述了丛枝和外生两种菌根真菌与宿主植物间营养交换的最新研究进展,尤其是碳、氮、磷等几种重要营养物质的吸收与双向转运机制,以及营养交换在菌根形成中的潜在调控作用,并对目前存在的关键问题和未来研究方向进行了分析和展望,这对菌根模型的建立及菌根效益的优化具有重要意义.     

内生真菌和丛枝菌根真菌对羊草生长的影响

该研究比较了摩西球囊霉(Glmous mosseae)和幼套球囊霉(Glmous etunicatum)两种丛枝菌根真菌和内生真菌单独及混合接种对羊草(Leymus chinensis)生长的影响。结果表明, 内生真菌对2种菌根真菌的侵染均无显著影响, 内生真菌可极显著增加羊草的分蘖数、地上生物量、总生物量。内生真菌与菌根真菌之间的相互作用因菌根真菌种类而不同, 幼套球囊霉对宿主植物生长无明显影响且和内生真菌之间也无明显的相互作用; 单独接种摩西球囊霉显著增加羊草的地上、地下和总生物量, 当其与内生真菌共同存在时, 二者之间存在一定的拮抗作用。冗余分析结果表明, 在内生真菌-AM真菌-羊草共生体中, 内生真菌对宿主植物生长的影响最大, 摩西球囊霉对宿主植物生长也有一定的贡献, 幼套球囊霉对宿主植物生长无明显影响。     

丛枝菌根共生体的氮代谢运输及其生态作用

丛枝菌根真菌能与80%的陆生维管植物形成互惠共生关系,共生体的存在对促进植物营养吸收和提高抗逆性具有重要意义.丛枝菌根真菌从宿主植物获取其光合产物碳水化合物的同时,通过外生菌丝吸收各种氮源,有效增强了宿主植物对氮素的吸收,以及氮在植物居群和群落水平上的交流,改善了植物营养代谢,增强了植物应对外界环境胁迫的能力.而共生体对氮的吸收、转运,以及氮从真菌到宿主植物的传输、代谢机制至今仍有许多问题亟待解决.本文综述了当前丛枝菌根共生体中氮传输代谢的主要机制,以及碳、磷对共生体氮传输代谢的影响;从群落和生态系统水平,简要阐述了丛枝菌根真菌在植物中氮分配的作用和对宿主植物的生态学意义,并提出共生体中氮代谢的一些需要深入研究的问题.
     

杜鹃花科植物菌根的研究进展

杜鹃花科Ericaceae植物可与土壤真菌形成杜鹃花类菌根ericoid mycorrhizas（ERM）共生体,且广泛分布于全球不同的陆地生态系统,特别是在贫瘠、酸性等严酷的环境中占优势。杜鹃花科植物菌根类型多样,绝大多数宿主具有ERM,还有少量宿主具有其他类型的菌根结构,且常与暗隔内生菌（dark septate endophyte,DSE）并存;ERM的宿主植物除已知的杜鹃花科外,岩梅科Diapensiaceae植物也具有ERM结构;ERM真菌以子囊菌和担子菌为主,主要来自柔膜菌目Helotiales和蜡壳耳目Sebacinales;与杜鹃花科宿主形成ERM的真菌也常与壳斗科Fagaceae、松科Pinaceae等宿主植物形成外生菌根（ectomycorrhiza,ECM）结构;ERM对宿主植物在营养吸收、忍耐贫瘠环境、抵抗重金属污染等能力方面都有积极的促进作用,对环境变化的响应是多样的,生境和季节的变化对ERMF群落的组成和分布有着显著影响,资源比率变化可能改变ERM宿主与其他菌根或非菌根植物之间的竞争关系。本文回顾了近40多年来国内外有关ERM的研究进展,还对ERM研究的前景进行了展望,以期在理论和实践中对杜鹃花科及其菌根的研究能取得更丰硕的成果。     

接种微生物对大豆生长及其根际土壤的影响

对沙土中的大豆接种丛枝菌根真菌及丛枝菌根真菌与解磷菌和根瘤菌联合接种, 动态监测大豆的生长状况和营养吸收情况。结果表明, 在沙土中, 根瘤菌与丛枝菌根真菌的组合效应对豆科植物营养元素的改善最为有效。接种丛枝菌根真菌以及丛枝菌根真菌与其他微生物联合应用对宿主矿质营养吸收尤其是磷吸收有明显的促进作用, 种植30 d、45 d 和64 d 接菌处理植物叶片的平均全磷含量比对照分别高1.45%、73%和56%。接种微生物使植物从土壤中吸收氮、磷、钾元素的强度比对照高, 接菌植物根际土壤养分浓度低于对照。接菌植物生物量显著高于对照, 单接种丛枝菌根真菌处理、双接种丛枝菌根真菌与解磷菌、双接种丛枝菌根真菌与根瘤菌以及丛枝菌根真菌、解磷菌与根瘤菌三种菌剂混合处理的总生物量分别比对照高出181%、134%、153%和89%。丛枝菌根真菌与解磷菌和根瘤菌三种菌剂混合接种对植物的促生作用并不明显。     

菌根真菌与兰科植物氮营养关系的研究进展

兰科植物是典型的菌根植物。兰菌根是兰科植物根与真菌形成的菌根共生体。兰菌根真菌的营养来源影响宿主植物的生活方式和营养水平。氮是植物生长的主要限制因子。兰科植物具有富集氮的特征, 其组织和器官的氮含量通常高于同生境中的其他植物。该文综述了兰菌根真菌类别、兰科植物氮营养特征和兰菌根的氮转移机制等的研究进展, 以期为兰科植物资源的保护、再生及可持续利用的相关研究提供参考和借鉴。     

丛枝菌根共生体中碳、氮代谢及其相互关系

丛枝菌根共生体(arbuscular mycorrhiza, AM)是丛枝菌根真菌(arbuscular mycorrhizal fungi, AMF)与宿主植物之间形成的互惠共生形式.共生体中的碳、氮交换和代谢影响着宿主植物和共生真菌之间的营养平衡和资源重新分配,在物质和能量循环中发挥着重要作用.宿主植物光合固定的碳输送到真菌内,并且分解和释放真菌所需的生命物质和能量,包括促进孢子萌发、菌丝生长和提高氮等营养元素的吸收;而菌根真菌利用宿主植物提供的碳骨架和能量,发生氮的转化和运输,最终传递给宿主植物供其利用.本文综述了丛枝菌根共生体中碳、氮传输和代谢的主要模式,碳、氮的交互影响和调控机制,以促进丛枝菌根在可持续农业和生态系统中的应用.     

Specific interactions between arbuscular mycorrhizal fungi and plant growth-promoting bacteria: as revealed by different combinations

The interactions between two plant growth-promoting rhizobacteria (PGPR, Pseudomonas fluorescens SBW25 and Paenibacillus brasilensis PB177), two arbuscular mycorrhizal (AM) fungi (Glomus mosseae and Glomus intraradices) and one pathogenic fungus (Microdochium nivale) were investigated on winter wheat (Triticum aestivum cultivar Tarso) in a greenhouse trial. PB177, but not SBW25, had strong inhibitory effects on M. nivale in dual culture plate assays. The results from the greenhouse experiment show very specific interactions; for example, the two AM fungi react differently when interacting with the same bacteria on plants. Glomus intraradices (single inoculation or together with SBW25) increased plant dry weight on M. nivale-infested plants, suggesting that the pathogenic fungus is counteracted by G. intraradices, but PB177 inhibited this positive effect. This is an example of two completely different reactions between the same AM fungus and two species of bacteria, previously known to enhance plant growth and inhibit pathogens. When searching for plant growth-promoting microorganisms, it is therefore important to test for the most suitable combination of plant, bacteria and fungi in order to achieve satisfactory plant growth benefits.     

我国北方农田土壤中AM真菌的多样性

AM真菌是农业生态系中一类重要的土壤微生物,它在农田土壤中的发生和分布受多种环境因素的影响。为深入了解我国北方农田土壤中AM真菌的多样性规律,于2000年在河北、山东的农田土壤中采集有代表性的土样127个。通过进一步扩繁、纯化,从中分离出AM真菌5属22种,鉴定了20个种,包括一个国内新记录种沾屑球囊霉(Glomus spurcum)。分析AM真菌的多样性特点及其影响因素发现,农田土壤中以球囊霉属(Glomus)的频度最高,其次为无梗囊霉属(Acaulospora);优势种类为幼套球囊霉(Glomus etunicatum)和摩西球囊霉(Glomus mosseae).土壤速效磷含量、pH状况主要对孢子密度产生影响,对种群分布影响不大。宿主植物类型对AM真菌的侵染状况和多样性影响较大;比较玉米(Zea mays)、甘薯(Ipomoea batatas)根区AM真菌的种群组成后发现两者有所不同,但优势种一致.     

Interaction between Glomus mosseae and soil yeasts on growth and nutrition of cowpea

A glass house experiment was conducted to study the interaction between the mycorrhizal fungus, Glomus mosseae and six soil yeasts (Rhodotorula mucilaginosa, Metschnikowia pulcherrima, Trichosporon cutaneum var. cutaneum, Saccharomyces cerevisiae, Cryptococcus laurentii, Debaryomyces occidentalis var. occidentalis), and their effect on growth and nutrition of cowpea. All the yeasts had a synergistic interaction with the mycorrhizal fungus and dual inoculation improved plant growth compared to single inoculation with G. mosseae alone. Nitrogen and phosphorus uptake of plants was also enhanced significantly in G. mosseae and soil yeasts combinations. Growth, N, P, chlorophyll and phenol content and yield of cowpea were highest in plants treated with G. mosseae+R. mucilaginosa. Mycorrhizal root colonization, spore numbers and population of yeasts in the root zone soil were also highest in the treatment G. mosseae+R. mucilaginosa and least in the uninoculated plants.     

Effectiveness of autochthonous bacterium and mycorrhizal fungus on Trifolium growth, symbiotic development and soil enzymatic activities in Zn contaminated soil

AIMS: This study investigates how autochthonous micro-organisms [bacterium and/or arbuscular mycorrhizal (AM) fungi] affected plant tolerance to Zn contamination. METHODS AND RESULTS: Zinc-adapted and -nonadapted Glomus mosseae strains protected the host plant against the detrimental effect of Zn (600 microg g(-1)). Zn-adapted bacteria increased root growth and N, P nutrition in plants colonized by adapted G. mosseae and decreased the specific absorption rate (SAR) of Cd, Cu, Mo or Fe in plants colonized by Zn-nonadapted G. mosseae. Symbiotic structures (nodule number and extraradical mycelium) were best developed in plants colonized by those Zn-adapted isolates that were the most effective in increasing plant Zn tolerance. The bacterium also increased the quantity and quality (metabolic characteristics) of mycorrhizal colonization, with the highest improvement for arbuscular vitality and activity. Inocula also enhanced soil enzymatic activities (dehydrogenase, beta-glucosidase and phosphatase) and indol acetic acid (IAA) accumulation, particularly in the rhizosphere of plants inoculated with Zn-adapted isolates. CONCLUSIONS: Glomus mosseae strains have a different inherent potential for improving plant growth and nutrition in Zn-contaminated soil. The bacterium increased the potential of mycorrhizal mycelium as inoculum. SIGNIFICANCE AND IMPACT OF THE STUDY: Mycorrhizal performance, particularly that of the autochthonous strain, was increased by the bacterium and both contributed to better plant growth and establishment in Zn-contaminated soils.     

Arbuscular mycorrhizal fungal application to improve growth and tolerance of wheat (Triticum aestivum L.) plants grown in saline soil

A pot experiment was conducted to examine the effects of three different arbuscular mycorrhizal fungi, Glomus mosseae, G. deserticola and Gigaspora gergaria, on growth and nutrition of wheat (Triticum aestivium L. cv. Henta) plants grown in saline soil. Under saline condition, mycorrhizal inoculation significantly increased growth responses, nutrient contents, acid and alkaline phosphatases, proline and total soluble protein of wheat plants compared to non-mycorrhizal ones. Those stimulations were related to the metabolic activity of the each mycorrhizal fungus. The localization of succinate dehydrogenase “SDH” (as a vital stain for the metabolically active fungus) in the arbuscular mycorrhizal fungi was variable. In general, mycorrhizal shoot plant tissues had significantly higher concentrations of P, N, K and Mg but lower Na concentration than those of non-mycorrhizal plants. In saline soil, growth and nutrition of wheat plants showed a high degree of dependency on mycorrhizal fungi (especially G. mosseae). The use of the nitroblue tetrazolium chloride method as a vital stain for SDH activity showed that all the structures of mycorrhizal infections in the wheat plant estimated by the trypan blue staining (non-vital stain) were not metabolically active. Interestingly, the reduction in Na uptake along with associated increases in P, N and Mg absorption and high proline, phosphatase activities and chlorophyll content in the mycorrhizal plants could be important for salt alleviation in plants growing in saline soils.     

培养容器容积对AM真菌生长发育的影响

研究宿主植物栽培容器对丛枝菌根(Arbuscularmycorrhizae,AM)真菌Glomusmosseae生长发育的影响。结果表明:小容积容器的根系密度相对较大,在菌根共生体建立初期,菌根真菌繁殖体与根接触的机会增大,对于菌根真菌的迅速侵染及共生体的迅速建立非常有利,同时还增大了根外菌丝二次侵染的机会,从而使菌根真菌生长发育形成了一个良性循环,最终有利于根外孢子的形成。容器对共生体的影响决不是简单的盆的体积问题,而与其面积和体积之比有关,也和种植密度有密切关系。     

Proteomic analysis as a tool for investigating arsenic stress in Pteris vittata roots colonized or not by arbuscular mycorrhizal symbiosis

Pteris vittata can tolerate very high soil arsenic concentration and rapidly accumulates the metalloid in its fronds. However, its tolerance to arsenic has not been completely explored. Arbuscular mycorrhizal (AM) fungi colonize the root of most terrestrial plants, including ferns. Mycorrhizae are known to affect plant responses in many ways: improving plant nutrition, promoting plant tolerance or resistance to pathogens, drought, salinity and heavy metal stresses. It has been observed that plants growing on arsenic polluted soils are usually mycorrhizal and that AM fungi enhance arsenic tolerance in a number of plant species. The aim of the present work was to study the effects of the AM fungus Glomus mosseae on P. vittata plants treated with arsenic using a proteomic approach. Image analysis showed that 37 spots were differently affected (21 identified). Arsenic treatment affected the expression of 14 spots (12 up-regulated and 2 down-regulated), while in presence of G. mosseae modulated 3 spots (1 up-regulated and 2 down-regulated). G. mosseae, in absence of arsenic, modulated 17 spots (13 up-regulated and 4 down-regulated). Arsenic stress was observed even in an arsenic tolerant plant as P. vittata and a protective effect of AM symbiosis toward arsenic stress was observed.     

Effects of Arbuscular-Mycorrhizal Glomus Species on Drought Tolerance: Physiological and Nutritional Plant Responses

The tolerance of lettuce plants (Lactuca sativa L. cv. Romana) to drought stress differed with the arbuscular-mycorrhizal fungal isolate with which the plants were associated. Seven fungal species belonging to the genus Glomus were studied for their ability to enhance the drought tolerance of lettuce plants. These fungi had different traits that affected the drought resistance of host plants. The ranking of arbuscular-mycorrhizal fungal effects on drought tolerance, based on the relative decreases in shoot dry weight, was as follows: Glomus deserticola > Glomus fasciculatum > Glomus mosseae > Glomus etunicatum > Glomus intraradices > Glomus caledonium > Glomus occultum. In this comparative study specific mycorrhizal fungi had consistent effects on plant growth, mineral uptake, the CO(inf2) exchange rate, water use efficiency, transpiration, stomatal conductance, photosynthetic phosphorus use efficiency, and proline accumulation under either well-watered or drought-stressed conditions. The ability of the isolates to maintain plant growth effectively under water stress conditions was related to higher transpiration rates, levels of leaf conductance, and proline, N, and P contents. Differences in proline accumulation in leaves among the fungal symbioses suggested that the fungi were able to induce different degrees of osmotic adjustment. The detrimental effects of drought were not related to decreases in photosynthesis or water use efficiency. Neither of these parameters was related to P nutrition. The differences in P and K acquisition, transpiration, and stomatal conductance were related to the mycorrhizal efficiencies of the different fungi. Our observations revealed the propensities of different Glomus species to assert their protective effects during plant water stress. The greater effectiveness of G. deserticola in improving water deficit tolerance was associated with the lowest level of growth reduction (9%) under stress conditions. The growth of plants colonized by G. occultum was reduced by 70% after a progressive drought stress period. In general, the different protective effects of the mycorrhizal isolates were not associated with colonizing ability. Nevertheless, G. deserticola was the most efficient fungus and exhibited the highest levels of mycorrhizal colonization, as well as the greatest stimulation of physiological parameters.     

Xyloglucanases in the interaction between saprobe fungi and the arbuscular mycorrhizal fungus Glomus mosseae

We studied the production of xyloglucanase enzymes of pea and lettuce roots in the presence of saprobe and arbuscular mycorrhizal (AM) fungi. The AM fungus Glomus mosseae and the saprobe fungi Fusarium graminearum, Fusarium oxysporum-126, Trichoderma harzianum, Penicillium chrysogenum, Pleurotus ostreatus and Aspergillus niger were used. G. mosseae increased the shoot and root dry weight of pea but not of lettuce. Most of the saprobe fungi increased the level of mycorrhization of pea and lettuce, but only P. chrysogenum and T. harzianum inoculated together with G. mosseae increased the dry weight of pea and lettuce respectively. The AM and saprobe fungi increased the production of xyloglucanases by plant roots. The level of xyloglucanase activities and the number of xyloglucanolytic isozymes in plants inoculated with G. mosseae and most of the saprobe fungi tested were higher than when both microorganisms were inoculated separately. The possible relationship between xylogucanase activities and the ability of AM and saprobe fungi to improve the dry weight and AM root colonization of plants was discussed.     

菌根植物根际环境对污染土壤中Cu、Zn、Pb、Cd形态的影响

采用根垫法和连续形态分析技术,分析了生长在污灌土壤中菌根小麦和无菌根小麦根际Ｃｕ、Ｚｎ、Ｐｂ、Ｃｄ的形态分布和变化趋势。结果表明,下对照土壤相比,菌根际土壤中交换态Ｃｕ含量显著增加,交换态Ｃｄ呈减少的趋势;与非菌根际相比,Ｃｕ、Ｚｎ、Ｐｂ的有机结合态在菌根根际中显著增加,而４种测定金属２的碳酸盐态和铁锰氧化态都没有显著改变,该结果表明,植物根系能影响根际中金属形态的变化,且菌根比无菌根的影响程度大