宿主植物栽培密度对AM真菌生长发育的影响

温室盆栽条件下宿主植物高粱(SorghumvulgarePers.)的栽培密度对丛枝菌根(Arbuscularmycorrhizae,AM)真菌Glomusmosseae(Nicol.&Gerd.)Gerdemann&Trappe生长发育的影响试验结果表明:60株/盆密度处理的根外菌丝量及孢子数均高于其它处理。在一定栽培密度下(20~60株/盆),植株根系可溶性糖浓度与根外菌丝量呈显著负相关,与菌根侵染率呈显著正相关。植株根中磷浓度与根外菌丝量、根外菌丝量与孢子数均呈显著正相关。植株根中磷浓度与菌根侵染率呈显著负相关。结果说明:适当密植虽对植株生长有一定影响,但却促进了真菌的生长,此时菌根共生体有可能由互惠共生开始向偏利共生或弱寄生转化。密植作为一种调控手段,在菌剂生产中能获得较大数量的侵染根段、菌丝及孢子等繁殖体。     

宿主植物栽培密度对AM真菌生长发育的影响*

温室盆栽条件下宿主植物高粱(SorghumvulgarePers.)的栽培密度对丛枝菌根(Arbuscularmycorrhizae,AM)真菌Glomusmosseae(Nicol.&Gerd.)Gerdemann&Trappe生长发育的影响试验结果表明:60株/盆密度处理的根外菌丝量及孢子数均高于其它处理。在一定栽培密度下(20~60株/盆),植株根系可溶性糖浓度与根外菌丝量呈显著负相关,与菌根侵染率呈显著正相关。植株根中磷浓度与根外菌丝量、根外菌丝量与孢子数均呈显著正相关。植株根中磷浓度与菌根侵染率呈显著负相关。结果说明:适当密植虽对植株生长有一定影响,但却促进了真菌的生长,此时菌根共生体有可能由互惠共生开始向偏利共生或弱寄生转化。密植作为一种调控手段,在菌剂生产中能获得较大数量的侵染根段、菌丝及孢子等繁殖体。     

银杏根际丛枝菌根真菌生长与根系黄酮含量的相关性研究

试验通过调查银杏根际丛枝菌根真菌的菌丝体长度、孢子密度及根系菌根侵染率,并测定银杏根系黄酮含量的季节性变化,研究二者的变化规律,分析相关关系。试验结果表明,年周期内银杏根际丛枝菌根真菌菌丝体长度、孢子密度与根系黄酮类化合物含量呈规律性变化:1月~3月根际丛枝菌根真菌菌丝长度有限,孢子密度、根系菌根侵染率与根系黄酮类化合物含量都最低;3月上中旬皆迅速增加,到9月达到全年最高峰;11月后,丛枝菌根真菌菌丝长度、孢子密度及根系菌根侵染率与根系黄酮类化合物含量均有所下降。通过数学模型分析,银杏根际丛枝菌根真菌菌丝长度、孢子密度及根系菌根侵染率与根系黄酮类化合物含量表现显著的正相关。     

营养液强度对AM真菌生长发育的影响*

研究了在贫营养基质中不同强度Hoagland营养液对丛枝菌根(Arbuscular mycorrhizae, M)真菌Glomus versiforme生长发育的影响。结果表明:本试验条件下,菌根侵染率、菌丝量、孢子数间呈显著正相关。在施加5%~50%强度Hoagland营养液时, 菌根真菌的生长与宿主植物高粱根中磷浓度、可溶性糖浓度密切相关,而与氮浓度无显著相关。由此认为:在盆栽生产菌根菌剂时,基质中存在一个临界磷浓度,在这个临界浓度之下,菌根真菌的生长发育随磷浓度的提高而增长,超过该临界浓度则会随磷浓度的提高而下降。施用20%、50%强度Hoagland营养液对菌根真菌生长最为有利,其菌根侵染率、菌丝量、孢子数均高于其它处理,因此认为:宿主植物—菌根真菌之间共生关系的基础是营养条件,基质中养分的高低会影响互惠共生关系的建立和发展。在高质量菌剂生产中, 菌根共生体双方的生长发育完全可以由人工控制。施加营养液是一种有效的调控手段,有可能使共生平衡向有利于菌根真菌生长发育的方向倾斜,使真菌得到最大程度的生长。     

营养液强度对AM真菌生长发育的影响

研究了在贫营养基质中不同强度 Hoagland 营养液对丛枝菌根(Arbuscular mycorrhizae,M) 真菌 Glomus versiforme 生长发育的影响。结果表明：本试验条件下,菌根侵染率、菌丝量、孢子数间呈显著正相关。在施加5％～50％强度。Hoagland 营养液时,菌根真菌的生长与宿主植物高粱根中磷浓度、可溶性糖浓度密切相关,而与氮浓度无显著相关。由此认为：在盆栽生产菌根菌剂时,基质中存在一个临界磷浓度,在这个临界浓度之下,菌根真菌的生长发育随磷浓度的提高而增长,超过该临界浓度则会随磷浓度的提高而下降。施用20％、50％强度 Hoagland 营养液对菌根真菌生长最为有利,其菌根侵染率、菌丝量、孢子数均高于其它处理,因此认为：宿主植物一菌根真菌之间共生关系的基础是营养条件,基质中养分的高低会影响互惠共生关系的建立和发展。在高质量菌剂生产中,菌根共生体双方的生长发育完全可以由人工控制。施加营养液是一种有效的调控手段,有可能使共生平衡向有利于菌根真菌生长发育的方向倾斜,使真菌得到最大程度的生长。     

营养液强度对AM真菌生长发育的影响

研究了在贫营养基质中不同强度Hoagland营养液对丛枝菌根(Arbuscularmycorrhizae,M)真菌Glomus versiforme生长发育的影响.结果表明本试验条件下,菌根侵染率、菌丝量、孢子数间呈显著正相关.在施加5%～50%强度Hoagland营养液时,菌根真菌的生长与宿主植物高粱根中磷浓度、可溶性糖浓度密切相关,而与氮浓度无显著相关.由此认为在盆栽生产菌根菌剂时,基质中存在一个临界磷浓度,在这个临界浓度之下,菌根真菌的生长发育随磷浓度的提高而增长,超过该临界浓度则会随磷浓度的提高而下降.施用20%、50%强度Hoagland营养液对菌根真菌生长最为有利,其菌根侵染率、菌丝量、孢子数均高于其它处理,因此认为宿主植物-菌根真菌之间共生关系的基础是营养条件,基质中养分的高低会影响互惠共生关系的建立和发展.在高质量菌剂生产中,菌根共生体双方的生长发育完全可以由人工控制.施加营养液是一种有效的调控手段,有可能使共生平衡向有利于菌根真菌生长发育的方向倾斜,使真菌得到最大程度的生长.     

植物根系复合共生体研究进展

植物根系与菌根真菌形成的互惠共生体,即菌根(mycorrhizas)是最常见、最广泛分布的共生体之一。自然条件下,一些植物的根系可同时形成由2种类型菌根构成的混合菌根,或菌根与细菌、菌根与放线菌、菌根与其他种类真菌构建的所谓复合共生体。文中从复合共生体的概念入手,简要介绍混合菌根、菌根与细菌、菌根与放线菌、菌根与其他真菌构建的复合共生体的多样性、形态解剖特征、生长发育及其功能等方面的研究概况,旨在为推进该领域的研究提供依据和借鉴的思路。     

植物与菌根菌

菌根是土壤中的真菌与高等植物根系所形成的共生体。共生真菌从植物体内获得碳水化合物等营养物质,而植物根也从真菌那里得到所需的营养元素和水,从而互利共生,共同进化。有趣的是,有些真菌对于一种植物来说是菌根菌,而对另一种植物来说可能是寄生菌或病原菌。据统计,种子植物中９５％以上的种能与接合菌、子囊菌、担子菌等亚门的真菌共生,形成菌根。菌根学者习惯上根据其形态解剖学特征,将菌根分为三大类：外生菌根、内生菌根、内外生菌根。外生菌根是菌根真菌菌丝体包围植物尚未木栓化的营养根形成的,其菌丝体不侵染到皮层细胞内…     

不同林龄杉木人工林菌根侵染特征研究

丛枝菌根真菌是一种通过土壤侵染植物根系,与寄主植物互利共生的重要有益真菌。探究不同林龄杉木林中菌根侵染状况与土壤养分的变化规律,有利于深入认识丛枝菌根真菌—杉木相互作用的养分调控因素,从而为改善杉木人工林土壤肥力、促进杉木林可持续经营提供依据。分别选取10a、25a、45a杉木纯林,分析了不同林分菌根侵染率与孢子密度及部分土壤养分因子(全磷、速效磷、全钾、速效钾)的关系。结果表明:(1)菌根侵染率与孢子密度均呈现出随林龄增大而增大的趋势,pH随林龄增大而减少的趋势;(2)根际土中磷的含量总体偏低,而且受到土壤酸化流失和丛枝菌根真菌积累的双重影响呈现出先减少后增加的趋势;(3)虽然有效钾含量随林龄变化趋势不显著,但丛枝菌根真菌能促进土壤钾的积累。因此,丛枝菌根真菌能有效调控根际土的养分动力学特征,减缓土壤酸化造成的养分流失。     

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.     

Hiding in a crowd—does diversity facilitate persistence of a low-quality fungal partner in the mycorrhizal symbiosis?

Given that arbuscular mycorrhizal (AM) fungi are not consistently beneficial to their host plants, it is difficult to explain the evolutionary persistence of this relationship. We tested the hypothesis that increasing either fungal or host biodiversity allows an AM fungus to persist on a host where it shows little benefit. We found that growing such a fungus (an isolate of Glomus custos associating with Plantago laceolata) in combination with certain fungi improved its success as measured by mtLSU DNA abundance. Increasing plant species richness facilitated the spread of this fungus as measured by spore density and fungal colonization; the role of host species richness was not as clear when looking at measures of root abundance. These results indicate that diversity in the AM symbiosis, both plant and fungal, can promote the persistence of low-quality fungi. By existing within a complex mycelial network fungal strains that show little growth benefit to their hosts have a better chance of persisting on that same host. This has the potential to promote selection for heterogeneous AM fungal communities on a small spatial scale.     

丛枝菌根真菌对羊草生物量和氮磷吸收及土壤碳的影响

采用大田试验的方法在内蒙古锡林格勒草原进行牧草接种试验,通过灭菌和未灭菌两种土壤研究接种丛枝菌根真菌Glomus mosseae和Glomus claroidium对内蒙古典型草原优势种羊草生长的影响.结果显示,接种丛枝菌根真菌对羊草的地上部干重未产生显著影响,但向未灭菌土壤中接种能显著增加羊草根系量,同时接种G.mosseae显著增加了地上部的N、P含量及吸收量,有效地改善了植株N、P营养,提高了牧草品质;2种菌对根系的营养吸收影响不同,接种G.mosseae在灭菌土壤和未灭菌土壤中均能显著增加根系的N、P吸收量,而接种G.claroidium仅在土壤未灭菌状态下增加根系N、P吸收量;接种对土壤中的菌丝密度未产生显著影响,但接种后土壤中微生物量碳有增加的趋势,短期内难以观察到接种对土壤有机碳的影响.研究表明,丛枝菌根真菌能够提高牧草对N、P吸收,促进牧草的生长,改善牧草品质,增强牧草根际微生物量碳.     

Impact of temperature on the arbuscular mycorrhizal (AM) symbiosis: growth responses of the host plant and its AM fungal partner

The growth response of the hyphae of mycorrhizal fungi has been determined, both when plant and fungus together and when only the fungus was exposed to a temperature change. Two host plant species, Plantago lanceolata and Holcus lanatus, were grown separately in pots inoculated with the mycorrhizal fungus Glomus mosseae at 20/18 degrees C (day/night); half of the pots were then transferred to 12/10 degrees C. Plant and fungal growth were determined at six sequential destructive harvests. A second experiment investigated the direct effect of temperature on the length of the extra-radical mycelium (ERM) of three mycorrhizal fungal species. Growth boxes were divided in two equal compartments by a 20 micro m mesh, allowing only the ERM and not roots to grow into a fungal compartment, which was either heated (+8 degrees C) or kept at ambient temperature. ERM length (LERM) was determined on five sampling dates. Growth of H. lanatus was little affected by temperature, whereas growth of P. lanceolata increased with temperature, and both specific leaf area (SLA) and specific root length (SRL) increased independently of plant size. Percentage of colonized root (LRC) and LERM were positively correlated with temperature when in symbiosis with P. lanceolata, but differences in LRC were a function of plant biomass. Colonization was very low in H. lanatus roots and there was no significant temperature effect. In the fungal compartment LERM increased over time and was greatest for Glomus mosseae. Heating the fungal compartment significantly increased LERM in two of the three species but did not affect LRC. However, it significantly increased SRL of roots in the plant compartment, suggesting that the fungus plays a regulatory role in the growth dynamics of the symbiosis. These temperature responses have implications for modelling carbon dynamics under global climate change.     

Effect of diazotrophic bacteria isolated from a mycelium of arbuscular mycorrhizal fungi on colonization of maize roots by Glomus fistulosum

The inoculation of mycorrhizal maize plants with three isolates of microaerophilic diazotrophic bacteria obtained from the mycelium of arbuscular mycorrhizal fungi associated with three grasses (Arrhenatherum elatius - bacterial isolate ARR, Agropyrum repens - isolate AGR and Poa annua - isolate POA) caused no increase in nitrogen content in plant biomass. The inoculation with bacterial isolate ARR resulted in the decreased plant growth. Bacterial isolate AGR decreased the percentage of the root length colonized by arbuscular mycorrhizal fungus Glomus fistulosum. The inoculation with both mycorrhizal fungus and isolate POA increased significantly the concentration of phosphorus in plant shoots compared to uninoculated control. This revised version was published online in July 2006 with corrections to the Cover Date.     

丛枝菌根对枳实生苗抗旱性的影响研究

在自然水分干旱胁迫和胁迫解除复水条件下,研究了丛枝菌根对1年生枳实生苗生长和抗旱性的影响.结果表明,接种丛枝菌根真菌Glomusmosseae93显著增加枳实生苗的株高、茎粗和鲜重,提高了幼苗移栽成活率.在自然水分干旱胁迫和胁迫解除复水过程中,丛枝菌根提高或者极显提高了叶片可溶性糖含量、叶片和根系的可溶性蛋白质含量、超氧化物歧化酶活性、过氧化物酶活性和过氧化氢酶活性,从而提高了枳实生苗的渗透调节能力,增强了其保护系统能力,降低了细胞膜脂过氧化,使枳实生苗抗旱能力增强.表明丛枝菌根真菌增强寄主植物抗旱能力的作用机制与保护系统相关.     

Polyamines in humic acid and their effect on radical growth of lettuce seedlings

Linum usitatissimum, Sorghum bicolor and Triticum aestivum plants were further colonised by the arbuscular mycorrhizal fungus, Glomus mosseae, during a four week period of hydroponic culture after a pre-culture period of three weeks with the fungus in perlite substrate. The viability of mycorrhizal colonisation of T. aestivum was indicated by an initial experiment where G. mosseae from mycorrhizal plants colonised non-mycorrhizal plants when the plants were grown together in the same hydroponic container using modified Long Ashton nutrient solution. Intermittant aeration of the plant roots (2 h periods, four times per day) provided a compromise between adequate aeration and minimal disturbance of the fungus. In a second experiment, two nutrient media, modified Long Ashton and modified Knop plus Hoagland medium were compared for culturing G. mosseae on T. aestivum. A significantly higher root dry weight was found for the mycorrhizal versus the non-mycorrhizal wheat plants in modified Long Ashton nutrient medium, which contained 10 µM P and an organic buffer. Modified Knop plus Hoagland nutrient medium contained a high P concentration (0.9 mM) and did not produce viable cultures of mycorrhizal colonisation. In a third experiment, modified Long Ashton medium was used for hydroponic culture of mycorrhizal L. usitatissimum, S. bicolor and T. aestivum. The root colonisation percentages for T. aestivum (73%), S. bicolor (36%) and L. usitatissimum (65%) were within the range of colonisation rates obtained with solid substrate culture in perlite. Viability of the mycorrhizal structures in hydroponic culture was assessed by monitoring activity of fungal succinate dehydrogenase and found to be similar to cultures in perlite. No difference in the P concentration of mycorrhizal and non-mycorrhizal plants was observed, possibly owing to the lack of diffusion limits for P in hydroponic solution. This report describes a system for the viable culture of G. mosseae with different plant species where a high mycorrhizal colonisation rate was produced under conditions of a short culture period using intermittent aeration, a low concentration of P supply and an organic buffer.     

Chemotropism in the arbuscular mycorrhizal fungus Glomus mosseae

In this work, we report the occurrence of chemotropism in the arbuscular mycorrhizal (AM) fungus Glomus mosseae. Fungal hyphae were able to respond to host-derived signals by reorienting their growth towards roots and to perceive chemotropic signals at a distance of at least 910 microm from roots. In order to reach the source of chemotropic signals, hyphal tips crossed interposed membranes emerging within 1 mm from roots, eventually establishing mycorrhizal symbiosis. The specificity of chemotropic growth was evidenced by hyphal growth reorientation and membrane penetration occurring only in experimental systems set up with host plants. Since pre-symbiotic growth is a critical stage in the life cycle of obligate AM fungal symbionts, chemotropic guidance may represent an important mechanism functional to host root location, appressorium formation and symbiosis establishment.     

AM真菌在煤矿废弃物中生态适应性的初步研究

以粉煤灰、草炭、蛭石、河沙为培养基质,分别对4种不同AM真菌:Glomus mosseae,G.diaphanum,G.intraradices和G.versiforme的生态适应性进行研究。结果表明,菌根的侵染率、孢子密度和菌丝长度分别与菌根真菌种类、培养基质状况及寄主植物种类有关。4种基质的扩繁效果顺序为:河沙>粉煤灰>草炭>蛭石。G.mosseae和G.diaphanum在基质中的产孢量和菌丝长度优于G.intraradices和G.versiforme,可作为优势菌株。4种菌根真菌在粉煤灰中对寄主的侵染率均达到60%以上,粉煤灰作为菌根真菌培养基质具有更大潜力和实际应用价值。     

亚热带草地中植物优势种与从属种对AM真菌的差异性生长反应

AM真菌能够影响植物生态系统的群落结构.以亚热带草地生态系统为研究对象,调查了两块草地中优势种和从属种的菌根,并在盆栽试验中比较了优势种和从属种对AM真菌的土著菌种和外源菌种Glomus mosseae的生长反应、养分吸收.结果表明,两块草地各自的优势种藿香蓟和两耳草对土著菌种的菌根依赖性分别是41.5%和77.4%,远远高于从属种莎草和毛蓼（16.0%和7.9%）;但是它们对Glomus mosseae的菌根依赖性有所变化,分别是79.6%、44.2%、74.1%和24.9%.这表明,土著菌种是优势种和从属种的形成机制之一,而外源菌种可能改变基于土著菌种而形成的植物群落结构.植株磷营养的分析结果表明,AM真菌对优势种和从属种生长的促进与对磷吸收的促进高度相关,表明AM真菌促进养分吸收是其影响植物群落结构的机制之一.