辽宁省八种兰科植物根内生真菌多样性

兰科植物的生存强烈依赖菌根真菌,研究兰科菌根真菌对兰科植物的保护有重要作用。本研究以辽宁省的无柱兰(Amitostigma gracile)、二叶舌唇兰(Platanthera chlorantha)、小斑叶兰(Goodyera repens)、蜻蜓兰(Tulotis fuscescens)、山兰(Oreorchis patens)、羊耳蒜(Liparis japonica)、长苞头蕊兰(Cephalanthera longibracteata)和绶草(Spiranthes sinensis) 8种属于极小种群的野生兰科植物为例,利用第二代测序技术对其根内生真菌多样性进行了研究。结果表明:无柱兰、二叶舌唇兰、小斑叶兰和山兰都偏好与角担菌科(Ceratobasidiaceae)真菌共生,羊耳蒜偏好与胶膜菌科(Tulasnellaceae)真菌共生;长苞头蕊兰主要与革菌科(Thelephoraceae)和蜡壳耳科(Sebacinaceae)真菌共生;绶草不仅能与丝核菌属(Rhizoctonia)真菌共生,还能与蜡壳耳科真菌共生;同种兰科植物的不同植株在同一生境下所选择的菌根真菌有差异,而同一地点的不同兰科植物的菌根真菌群落各不相同。由此可见,兰科植物根中菌根真菌的组成并非完全受植物自身控制,但主要菌根真菌仍取决于兰科植物的选择;这8种兰科植物根中的真菌绝大多数为非菌根真菌,而菌根真菌的丰度通常很低,这可能是辽宁地区兰科植物稀少的原因之一。     

兰科菌根研究综述

兰科菌根是一种内生菌根,主要寄生于兰科（Orchidaceae）植物的种子及根系上。对兰科菌根真菌的分类及真菌资源多样性、兰科菌根的形态和菌根对兰科植物的效应等最新研究进展进行了综述。目前研究已知,感染兰科植物根部并能与之共生的真菌绝大多数属于担子菌门（Basidiomycota）和半知菌门（Deuteromycotha）,也有部分属于子囊菌门（Ascomycota）;兰科菌根的形成可分为两种情况：一是对兰科植物种子的侵染;二是对成长新根的侵染。菌根真菌对兰科植物的种子萌发及植株生长发育均有一定影响。     

不同生境下五唇兰根部可培养内生细菌多样性研究

兰科植物内生细菌与菌根真菌的协作对宿主植物的生长、抗病、抗逆及植物修复环境能力等具有重要意义,揭示其内生细菌多样性及与生境之间的关系有助于阐明兰科植物的适应与进化机制。本研究基于16SrDNA序列分析探讨了不同生境下东南亚特有种五唇兰根部可培养内生细菌多样性及其空间异质性。结果表明:从不同生境下五唇兰根部共分离出内生细菌59株,其中从土生型五唇兰根部分离出内生细菌45株(76.27%),从石生型五唇兰根部分离出内生细菌14株(23.73%);基于内生细菌16SrDNA序列同源性分析及构建的系统发育树显示,五唇兰根部内生细菌分属于7属,即芽孢杆菌属(Bacillus)、伯克氏菌属(Burkholderia)、草酸菌属(Pandoraea)、土壤杆菌属(Agrobacterium)、类芽孢杆菌属(Paenibacillus)、泛菌属(Pantoea)、欧文氏菌属(Erwinia),其中优势属为芽孢杆菌属,次优势属为泛菌属和伯克氏菌属;多样性分析显示,土生型五唇兰根部内生细菌群落的Shannon多样性指数大于石生型五唇兰,不同生境下五唇兰根部内生细菌群落结构差异极显著(P0.01)。土生型五唇兰根部内生细菌群落优势属为芽孢杆菌属和泛菌属,石生型五唇兰根部内生细菌群落优势属为芽孢杆菌属和伯克氏菌属。     

实验室条件下五唇兰菌根真菌专一性研究

利用从高原温带兰科植物菌根中获得的22个菌根真菌菌株, 对五唇兰(Doritis pulcherrima)进行了室内种子萌发、原球茎分化和组培苗回接试验, 从交叉回接的角度对附生兰科植物与菌根真菌的生理专一性进行了探讨。经过20周的共生培养, 只有编号为Cf1和Mm1的两个菌株使种子表现出种胚明显膨大的萌发迹象; 9个菌株能够促使原球茎较好地分化发育出根叶; 11个菌株处理苗的平均鲜重增长率高于对照组(156.25%), 其中Mm1的效果达到极显著水平(p = 0.01)。通过根切片显微观察, 在原球茎分化根和回接效果良好的处理苗的根皮层组织发现典型的菌丝团结构, 表明菌根体系已成功建立。温带地生兰菌根真菌对五唇兰种子萌发、原球茎发育和幼苗生长等3个重要生长阶段影响的试验显示, 五唇兰的种子和菌根真菌的共生萌发效果不佳, 而原球茎及幼株更容易与之建立良好的共生关系。同时, 也没有发现同一个真菌菌株能够对五唇兰的种子、原球茎和幼苗均产生促进作用。研究结果表明, 五唇兰的菌根真菌专一性因生理生长阶段的不同而存在差异。     

野生五唇兰根部内生真菌多样性研究

兰科植物根部的内生真菌在兰科植物的整个生活史中起着重要的作用, 为了解不同生境不同类型的兰科植物内生真菌菌群的多样性, 作者于2004年7月至2005年10月, 以海南岛霸王岭自然保护区内的野生五唇兰(Doritis pulcherrima)作为实验材料, 对不同生境、不同形态的五唇兰植株根部的内生真菌群落多样性进行了研究。从附生于石上及生于杂木林或灌丛中、叶背绿色及叶背紫红色的五唇兰植株新鲜营养根段中共分离出83株内生真菌, 鉴定为19个属, 其中包括培养基筛选实验中分离出的30株14属。镰刀菌属(Fusarium)(24.1%)和丝核菌属 (Rhizocto-nia)(14.5%)为优势属。两种叶色的五唇兰内生真菌群落丰富度较为一致; 而两种不同生境中的五唇兰内生真菌群落丰富度则表现出较大的差异: 附生于灌木的五唇兰内生真菌群落Shannon多样性指数远高于附生岩石的。研究结果表明五唇兰内生真菌多样性更多地受生境的影响而不是受植株形态类型的影响。     

华北特有腐生型兰科植物北京无喙兰根际土壤微生物多样性研究

北京无喙兰(Holopogon pekinensis X. Y. Mu & Bing Liu)为华北地区特有珍稀腐生型兰科植物,分布在海拔约1100 m的杂木林内,生境与本区域内其他腐生型兰科植物(常在1600 m以上桦木林中生长)显著不同。本研究针对北京玉渡山和百花山两个北京无喙兰种群的根际土壤样品开展基于高通量测序技术的根际土壤微生物多样性分析,解析北京无喙兰根际土壤微生物群落组成及多样性。测序分析结果显示,共得到4973个细菌OTU(Operational taxonomic unit),发现北京无喙兰根际土壤的优势细菌类群为变形菌门、放线菌门、拟杆菌门等7个门,优势属有MND1、硝化螺菌属(Nitrospira)和Haliangium等。1914个真菌OTU的分析结果表明,根际土壤优势真菌类群为子囊菌门、担子菌门、结合菌门等;优势属有Archaeorhizomyces、蜡壳耳属(Sebacina)和被孢霉属(Mortierella)等;优势真菌多为外生菌根真菌,可能是北京无喙兰潜在的菌根真菌。多样性指数分析显示,北京无喙兰玉渡山种群根际土壤中的真菌和细菌群落的丰富度和均匀度均高于百花山种群,各种群土壤微生物多样性与北京无喙兰所在种群的乔木种类多样性具有一定的相关性。     

银叶杜鹃和繁花杜鹃根部真菌的多样性

植物根系与真菌形成菌根, 在自然生态系统的物质能量循环中具有重要的生态功能。作者在四川省的中国杜鹃园选取银叶杜鹃(Rhododendron argyrophyllum)和繁花杜鹃(R. floribundum), 通过直接扩增杜鹃花根部真菌rDNA-ITS区片段, 来揭示该地区杜鹃花属植物根部真菌的多样性。ITS序列分析结果表明: 从两种杜鹃的根部共检测到41个真菌分类单元, 分别属于子囊菌纲的柔膜菌目(Helotiales)、散囊菌目(Eurotiales)、盘菌目(Pezizales)、假球壳目(Pleosporales)和担子菌纲的蜡壳耳目(Sebacinales)、伞菌目(Agaricales)、Erythrobasidiales、线黑粉菌目(Filobasidiales)。银叶杜鹃和繁花杜鹃根部真菌种类丰富, 包括了杜鹃花类菌根真菌、外生菌根真菌和其他类型真菌, 其中担子菌纲的蜡壳耳目和子囊菌纲的柔膜菌目占有较大比例。     

亚热带森林菌根植物根系真菌群落结构对氮磷添加的响应

植物根系真菌对维系植物的营养吸收和健康具有重要作用。本研究分析了不同菌根类型植物根系中真菌的群落结构对外源氮(N)、磷(P)、氮和磷(NP)输入的响应。试验采集了无添加(对照)和N、P、NP添加处理下亚热带森林3种菌根类型(丛枝菌根、外生菌根、欧石楠菌根)9种植物的根系，运用高通量测序技术检测根系中真菌的多样性和群落组成。结果表明：9种植物根系真菌群落均主要由担子菌门和子囊菌门组成；P添加下子囊菌门的相对多度显著低于对照，而担子菌门的相对多度显著高于对照。欧石楠菌根植物根系中子囊菌门的相对多度显著高于丛枝菌根和外生菌根植物，而其担子菌门的相对多度显著低于丛枝菌根和外生菌根植物。与对照相比，P添加显著降低了植物根系中真菌的α多样性，改变了不同菌根类型植物根系中真菌的群落组成，而N添加和菌根类型的影响不明显。与对照和N添加相比，NP添加使全部植物根系中真菌群落变异程度更大，即群落整体更加趋异，而外生菌根植物根系中的真菌群落比丛枝菌根植物根系中的真菌群落变异更小，即群落更趋同。综上，P养分是影响亚热带森林土壤中树木根系真菌群落结构的关键因素。本研究有助于提升对全球环境变化下亚热带地区植物根系...     

春兰和蕙兰菌根真菌rDNA ITS序列及共生专一性分析

春兰(Cymbidium goeringii)和蕙兰(Cymbidium faberi)是我国较为广泛分布的地生类型兰属植物,具有悠久的栽培历史和很高的经济价值.菌根真菌与兰科植物专一性关系一直是兰科茵根研究中的热点.该文对35株分离自浙江天目山野生春兰和蕙兰的菌根真菌进行了rDNA ITS序列分析,并在此基础上初步探讨了菌根真菌与春兰、蕙兰之间的专一性关系.结果表明,分离获得的菌根真菌与其共生兰属植物在种的层面具显著专一性,即物种是影响或决定浙江天目山地区春兰、蕙兰与共生菌根真菌专一性的重要因素;研究同时发现,自蕙兰同一条根分离获得的菌根真菌菌株间亦表现丰富的多样性差异.     

广西喀斯特地区毛唇芋兰根内与根际土壤真菌群落组成分析

为探索兰科(Orchidaceae)植物毛唇芋兰(Nervilia fordii)根内和根际土壤真菌群落多样性，该研究采用Illumina MiSeq高通量测序技术，分析了大新(DX)和龙州(LZ)两个样地(简称两地)毛唇芋兰根内和根际土壤的真菌组成。结果表明：(1)两地的毛唇芋兰根内和根际土壤真菌多样性很丰富，根际土壤真菌多样性均高于根内，主根的真菌多样性高于走茎。(2)通过测序共获得有效序列118 040条，207个可操作分类单元(OTUs)涉及8门19纲42目86科123属。(3)担子菌门(Basidiomycota)真菌是两地毛唇芋兰根内真菌的共同优势菌群，涉及胶膜菌科(Tulasnellaceae)、Trimorphomycetaceae、角担菌科(Ceratobasidiaceae)、马拉色菌科(Malasseziaceae)和小皮伞科(Marasmiaceae)等，其中优势科和优势属分别是胶膜菌科(75%)和瘤菌根菌属(Epulorhiza)(56%),而土壤中的优势菌属则是镰刀菌属(Fusarium)。综上认为，毛唇芋兰根内与根际土壤中的优势菌群既差异显著也存在一些共同...     

Influence of mycorrhizal fungi on seed germination and growth in terrestrial and epiphytic orchids

Epiphytes constitute over 70% of orchid diversity, but little is known about the functioning of their mycorrhizal associations. Terrestrial orchid seeds germinate symbiotically in soil and leaf litter, whereas epiphytic orchids may be exposed to relatively high light levels from an early stage of development and often produce green seeds. This suggests that seedlings of the two groups of orchids may differ in their responses to light and requirements for mycorrhiza-supplied carbon. The interactive effects of light, exogenous carbon and mycorrhizal status on germination and growth were investigated in vitro using axenic agar microcosms for one tropical epiphyte and three geophytic orchid species. The geophytic species strongly depended on their mycorrhiza for growth and this could not be substituted by exogenous sucrose, whereas the epiphytic species achieved 95% of the mycorrhizal seedling volume when supplied with exogenous sucrose in the dark. Mycorrhiza status strongly interacted with light exposure, enabling germination. Light inhibited or severely reduced growth, especially for the terrestrial orchids in the absence of mycorrhiza. For the first time, this study showed the parallel ecological importance of mycorrhizal fungi in overcoming light inhibition of seed germination and growth in both terrestrial and epiphytic orchids.     

Untangling above‐ and belowground mycorrhizal fungal networks in tropical orchids

Orchids typically depend on fungi for establishment from seeds, forming mycorrhizal associations with basidiomycete fungal partners in the polyphyletic group rhizoctonia from early stages of germination, sometimes with very high specificity. This has raised important questions about the roles of plant and fungal phylogenetics, and their habitat preferences, in controlling which fungi associate with which plants. In this issue of Molecular Ecology, Martos et al. (2012) report the largest network analysis to date for orchids and their mycorrhizal fungi, sampling a total of over 450 plants from nearly half the 150 tropical orchid species on Reunion Island, encompassing its main terrestrial and epiphytic orchid genera. The authors found a total of 95 operational taxonomic units of mycorrhizal fungi and investigated the architecture and nestedness of their bipartite networks with 73 orchid species. The most striking finding was a major ecological barrier between above‐ and belowground mycorrhizal fungal networks, despite both epiphytic and terrestrial orchids often associating with closely related taxa across all three major lineages of rhizoctonia fungi. The fungal partnerships of the epiphytes and terrestrial species involved a diversity of fungal taxa in a modular network architecture, with only about one in ten mycorrhizal fungi partnering orchids in both groups. In contrast, plant and fungal phylogenetics had weak or no effects on the network. This highlights the power of recently developed ecological network analyses to give new insights into controls on plant–fungal symbioses and raises exciting new hypotheses about the differences in properties and functioning of mycorrhiza in epiphytic and terrestrial orchids.     

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。     

Relationships between orchid and fungal biodiversity: Mycorrhizal preferences in Mediterranean orchids

Orchidaceae is one of the most species-rich angiosperm families, and all orchids are fully dependent on fungi for their seed germination and their life cycle. The level of specificity of the association between orchid species and fungi can be related to the number of co-occurring orchid species. To investigate orchid mycorrhizal associations in adult-photosynthetic orchids, 16 Mediterranean orchid species belonging to 4 genera (Anacamptis, Ophrys, Orchis, and Serapias) at 11 different sites were subjected to DNA-based analysis. Eighteen operational taxonomic units representing two fungal families, Tulasnellaceae and Ceratobasidiaceae, were identified. All examined orchid species associated with different mycorrhizal fungi. Interestingly, there was a positive correlation between number of orchid species and number of mycorrhizal. Monospecific populations showed a lower number of fungi, while sympatric populations had a higher number of mycorrhizal fungi. Our results showed that Mediterranean orchid species associated with a higher number of mycorrhizal fungi confirming as photosynthetic orchids are typically generalists toward mycorrhizal fungi. Thus, photosynthetic orchids exhibit low specificity for fungal symbionts showing the potential for opportunistic associations with diverse fungi reducing competition for nutrient. We suggest that these characteristics could confer symbiotic assurance particularly in habitat with resource limitations or prone to stressful conditions.     

The importance of associations with saprotrophic non-Rhizoctonia fungi among fully mycoheterotrophic orchids is currently under-estimated: novel evidence from sub-tropical Asia

Background and Aims Most fully mycoheterotrophic (MH) orchids investigated to date are mycorrhizal with fungi that simultaneously form ectomycorrhizas with forest trees. Only a few MH orchids are currently known to be mycorrhizal with saprotrophic, mostly wood-decomposing, fungi instead of ectomycorrhizal fungi. This study provides evidence that the importance of associations between MH orchids and saprotrophic non-Rhizoctonia fungi is currently under-estimated.Methods Using microscopic techniques and molecular approaches, mycorrhizal fungi were localized and identified for seven MH orchid species from four genera and two subfamilies, Vanilloideae and Epidendroideae, growing in four humid and warm sub-tropical forests in Taiwan. Carbon and nitrogen stable isotope natural abundances of MH orchids and autotrophic reference plants were used in order to elucidate the nutritional resources utilized by the orchids.Key Results Six out of the seven MH orchid species were mycorrhizal with either wood- or litter-decaying saprotrophic fungi. Only one orchid species was associated with ectomycorrhizal fungi. Stable isotope abundance patterns showed significant distinctions between orchids mycorrhizal with the three groups of fungal hosts.Conclusions Mycoheterotrophic orchids utilizing saprotrophic non-Rhizoctonia fungi as a carbon and nutrient source are clearly more frequent than hitherto assumed. On the basis of this kind of nutrition, orchids can thrive in deeply shaded, light-limiting forest understoreys even without support from ectomycorrhizal fungi. Sub-tropical East Asia appears to be a hotspot for orchids mycorrhizal with saprotrophic non-Rhizoctonia fungi.     

Studies of Mycorrhizal Fungi of Chinese Orchids and Their Role in Orchid Conservation in China—A Review

China has over 1,200 species of native orchids in nearly 173 genera. About one fourth of native species are of horticultural merit. Some species are of Chinese medicinal value. In fact, the demand on orchid species with high Chinese medicinal values such as Gastrodia elata, Dendrobium offcinale, along with demands on species of cultural importance, such as those in the genus of Cymbidium, is a major factor causing wild populations to diminish and in some cases, drive wild populations to the brink of extinction. These market demands have also driven studies on the role of mycorrhizal fungi in orchid seed germination, seedling and adult growth, and reproduction. Most of these mycorrhizal studies of Chinese orchids, however, are published in Chinese, some in medical journals, and thus overlooked by the mainstream orchid mycorrhizal publications. Yet some of these studies contained interesting discoveries on the nature of the mycorrhizal relationships between orchids and fungi. We present a review of some of these neglected publications. The most important discovery comes from the mycorrhizal studies on G. elata, in which the researchers concluded that those fungi species required to stimulate seed germination are different from those that facilitate the growth of G. elata beyond seedling stages. In addition, presence of the mycorrhizal fungi associated with vegetative growth of post-seedling G. elata hindered the germination of seeds. These phenomena were unreported prior to these studies. Furthermore, orchid mycorrhizal studies in China differ from the mainstream orchid studies in that many epiphytic species (in the genus of Dendrobium, as medicinal herbs) were investigated as well as terrestrial orchids (mostly in the genus Cymbidium, as traditional horticultural species). The different responses between epiphytic and terrestrial orchid seeds to fungi derived from roots suggest that epiphytic orchids may have a more general mycorrhizal relationship with fungi than do terrestrial orchid species during the seed germination stage. To date, orchid mycorrhizal research in China has had a strongly commercial purpose. We suggest that this continuing research on orchid mycorrhizal relationships are a solid foundation for further research that includes more rare and endangered taxa, and more in-situ studies to assist conservation and restoration of the endangered orchids. Knowledge on the identities and roles of mycorrhizal fungi of orchids holds one of the keys to successful restoration and sustainable use of Chinese orchids.     

Molecular identification of mycorrhizal fungi in Neuwiedia veratrifolia (Orchidaceae)

We here apply a previously described method for identification of single peloton orchid mycorrhiza to a key orchid group and extend the usefulness in the heterobasidiomycetes of an existing fungal database for identification of mycorrhizal fungi. We amplified and sequenced mitochondrial ribosomal large subunit DNA from fungi in roots of Neuwiedia veratrifolia (Orchidaceae), a member of the small subfamily Apostasioideae that is sister to the remainder of Orchidaceae, and used the extended database to identify the mycorrhizal fungi. Sequences from fungi cultured from Neuwiedia roots and from direct peloton amplifications were analyzed cladistically with sequences determined from reference fungal collections and published sequences. The fungi from Neuwiedia are referred to the heterobasidiomycetous orders Tulasnellales and Ceratobasidiales, indicating that apostasioids utilize the same fungi as other photosynthetic orchids. The majority of Neuwiedia mycobionts came together in a clade with Tulasnella species, but some were most closely related to Thanatephorus. In some cases members of these two clades were isolated from the same orchid plant, providing another example of multiple mycobionts occurring in a single plant.     

Diversity and host specificity of endophytic Rhizoctonia-like fungi from tropical orchids

All orchids have an obligate relationship with mycorrhizal symbionts. Most orchid mycorrhizal fungi are classified in the form-genus Rhizoctonia. This group includes anamorphs of Tulasnella, Ceratobasidium, and Thanatephorus. Rhizoctonia can be classified according to the number of nuclei in young cells (multi-, bi-, and uninucleate). From nine Puerto Rican orchids we isolated 108 Rhizoctonia-like fungi. Our isolates were either bi- or uninucleate, the first report of uninucleate Rhizoctonia-like fungi as orchid endophytes. We sequenced the internal transcribed spacer (ITS) region of nuclear ribosomal DNA from 26 isolates and identified four fungal lineages, all related to Ceratobasidium spp. from temperate regions. Most orchid species hosted more than one lineage, demonstrating considerable variation in mycorrhizal associations even among related orchid species. The uninucleate condition was not a good phylogenetic character in mycorrhizal fungi from Puerto Rico. All four lineages were represented by fungi from Tolumnia variegata, but only one lineage included fungi from Ionopsis utricularioides. Tropical epiphytic orchids appear to vary in degree of specificity in their mycorrhizal interactions more than previously thought.     

兰科菌根的生态学研究进展

兰科植物(Orchidaceae)是典型的菌根植物,自然条件下其种子的成功萌发和生长的早期阶段对菌根真菌有绝对的依赖性,在有些成年兰科植物中菌根真菌仍起着重要的作用。目前大部分兰科植物已为濒危物种,鉴于兰科植物天然的菌根共生关系,开展兰科植物和菌根真菌互作的生态学研究不仅具有极高的科研价值,更有助于兰科植物的物种保护和野生种群的生态恢复。近年研究表明,兰科植物对真菌的选择和二者共生关系的建立与菌根真菌的空间分布和丰度密切相关,然而当前对自然环境中兰科菌根真菌的实际分布还了解甚少,因此文章从生态学角度系统分析兰科植物与菌根真菌的关系,探讨该领域的研究热点,旨在为兰科菌根的生态学研究提供参考。     

Mycorrhizal fungal community composition in seven orchid species inhabiting Song Mountain,Beijing, China

Mycorrhizal fungi play an important role in the germination and growth of orchids essentially influencing their survival,abundance, and spatial distribution. In this study, we investigated the composition of the mycorrhizal fungal community in seven terrestrial orchid species inhabiting Song Mountain, Beijing, China, using Illumina MiSeq high-throughput sequencing. The mycorrhizal communities in the seven orchids were mainly composed of members of the Ceratobasidiaceae, Sebacinales, and Tulasnellaceae, while a number of ectomycorrhizal fungi belonging to the Russulaceae, Tricholomataceae, Thelephoraceae, and Cortinariaceae were occasionally observed. However, the dominant fungal associates and mycorrhizal community differed significantly among the orchid species as well as subhabitats. These findings confirm the previous observation that sympatric orchid species show different preferences for mycorrhizal fungi, which may drive niche partitioning and contribute to their cooccurrence.