密花石斛等六种兰科植物菌根的显微结构研究

本文对密花石斛等六种兰科植物根的显微结构进行了比较观察。结果表明,它们具有典型的兰科植物根,具根被和发达的皮层组织,皮层细胞内分布有针状结晶和菌根真菌形成的菌丝结,发现菌根真菌通过外皮层薄壁通道细胞或破坏根被组织和外皮层细胞侵入皮层细胞,形成内生菌根。     

墨兰菌根的结构及酸性磷酸酶定位研究

利用光学显微镜、电子显微镜及细胞化学方法,对墨兰菌根的结构和酸性磷酸酶定位进行了初步研究。结果表明墨兰具有典型的兰科植物根结构,发现该兰花的根的外皮层不具薄壁通道细胞,菌根真菌通过破坏部分根被和外皮层细胞而侵入根的皮层细胞并在细胞内形成菌丝结,侵入的菌丝被染菌皮层细胞质膜和电子透明物质包围,进一步被消化并聚集成衰败菌丝团块。酸性磷酸酶在染菌皮层细胞及包围菌丝的皮层细胞质膜和衰败菌丝细胞壁上有强烈的酶反应,衰败菌丝周围分布有许多单层膜的含酶小泡,它们可相互愈合形成大的含酶泡或与包围菌丝的质膜融合,类似于兰科植物共生原球茎中观察到的现象。说明皮层细胞可主动释放水解酶参与对菌丝的消化     

辽宁省9种兰科植物根内与根际土壤中真菌群落结构的差异

兰科植物的生存及生长高度依赖其根中的共生真菌,其中的菌根真菌更是对兰科植物的种子萌发与后续生长有着非常重要的作用,研究兰科植物根中的真菌,尤其是菌根真菌,对兰科植物的保护有重要作用。该研究利用第二代测序技术,对中国辽宁省境内的9种属于极小种群的兰科植物的根、根际土和根围土中的真菌群落和菌根真菌组成进行了研究。结果显示,兰科植物根中的真菌群落和根际土、根围土中的真菌群落具有显著差异。兰科植物根中的总操作分类单元(OTU)数目远小于根际土和根围土中的总OTU数目。同时,兰科植物根中菌根真菌的种类和丰度与根际土、根围土中菌根真菌的种类与丰度没有明显联系。FunGuild分析结果显示,丛枝菌根真菌在根际土与根围土中的丰度非常高,但在兰科植物的根中却数量极少。这些结果表明,兰科植物根中的真菌群落与土壤中的真菌群落在一定程度上是相互独立的。     

辽宁省9种兰科植物根内与根际土壤中真菌群落结构的差异

兰科植物的生存及生长高度依赖其根中的共生真菌, 其中的菌根真菌更是对兰科植物的种子萌发与后续生长有着非常重要的作用, 研究兰科植物根中的真菌, 尤其是菌根真菌, 对兰科植物的保护有重要作用。该研究利用第二代测序技术, 对中国辽宁省境内的9种属于极小种群的兰科植物的根、根际土和根围土中的真菌群落和菌根真菌组成进行了研究。结果显示, 兰科植物根中的真菌群落和根际土、根围土中的真菌群落具有显著差异。兰科植物根中的总操作分类单元(OTU)数目远小于根际土和根围土中的总OTU数目。同时, 兰科植物根中菌根真菌的种类和丰度与根际土、根围土中菌根真菌的种类与丰度没有明显联系。FunGuild分析结果显示, 丛枝菌根真菌在根际土与根围土中的丰度非常高, 但在兰科植物的根中却数量极少。这些结果表明, 兰科植物根中的真菌群落与土壤中的真菌群落在一定程度上是相互独立的。     

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。     

5种虾脊兰菌根显微结构观察

采用石蜡切片法观察5种虾脊兰菌根的显微结构、菌根真菌的侵入途径与分布特征,为更好地保护和开发利用虾脊兰属植物资源提供理论依据。结果表明:(1)5种虾脊兰菌根的显微结构由根被、皮层和中柱组成,根被细胞3～6层,皮层由9～13层薄壁细胞组成,韧皮部与木质部8～12束,呈辐射状相间排列,中柱中央为薄壁细胞组成的髓。(2)菌丝通过外皮层中的通道细胞侵入皮层,且皮层是内生菌根真菌寄居的主要区域,菌丝和菌丝结在靠近外皮层的几层皮层细胞中数量居多,菌丝在细胞核附近被消解,细胞核变形膨大。研究认为,5种虾脊兰可能拥有广泛的侵染能力较强的菌根真菌类型,使得这5种虾脊兰均具有较强的生态适应性。     

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。     

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。     

人工栽培铁皮石斛菌根的细胞学研究

从细胞学水平上研究了人工栽培铁皮石斛的菌根特征。结果表明:真菌与铁皮石斛根成功地形成了菌根,真菌菌丝穿透根被细胞,并在根被的某个细胞中定殖,然后经由外皮层的通道细胞进入皮层薄壁细胞;皮层薄壁细胞层正是真菌与植物体相互作用的活跃部位;真菌侵染大多数的皮层薄壁细胞,并不能侵染内皮层及中柱细胞,从而使根仍然保持生活力。     

Velamen and exodermis characters of West African epiphytic orchids in relation to taxonomic grouping and habitat tolerance

The velamen and exodermis of roots of 76 species of epiphytic orchids occurring in West Africa were examined and evaluated for the following characters: number of velamen layers; wall striations and hairs of the velamen; wall thickening and lignification of velamen and exodermal cells; size, and uniformity in shape and size, of velamen and exodermal cells. The term epi-velamen is proposed for the distinctive outermost layer of multi-seriate velamen. High correlation is reported between the number of velamen layers and taxonomic as well as habitat-tolerance groupings, together with lower, but still appreciable, correlation between the other characters evaluated and taxonomic and habitat-tolerance groupings.     

Comparative anatomy and systematics of Catasetinae (Orchidaceae)

Catasetinae consist of five genera of pseudobulbous Orchidaceae of the Neotropics. Anatomy is characterized by sunken, three-celled foliar hairs, mostly tetracytic stomatal apparatuses, superficial stomata, homogeneous mesophyll, foliar fibre bundles, collateral vascular bundles in a single row, xylem and phloem sclerenchyma associated with vascular bundles in leaves, conical, and rough-surfaced silica bodies adjacent to vascular bundle sclerenchyma; epidermal cells of pseudobulbs with heavily thickened outer walls, pseudobulb ground tissue of assimilatory and water-storage cells, scattered vascular bundles in pseudobulbs, and sclerenchyma and stegmata associated only with phloem of pseudobulbs; roots with thin-walled velamen cells and tenuous spirals of cell wall material, distinctive epivelamen cells, thin-walled exodermal cells and vascular tissue embedded in parenchyma. Except for mucilaginous idioblasts that occur in Mormodes and Cycnoches , there are few outstanding anatomical differences among the five genera. Thus, there are few anatomical characteristics of phylogenetic value. The monophyly of Catasetinae is supported by the presence of sunken foliar hairs. Our results support a close relationship between Clowesia and Catasetum , and between Mormodes and Cycnoches. Among the outgroups Pteroglossaspis is especially distinctive.     

Vegetative anatomy of subtribe Orchidinae (Orchidaceae)

Leaves in Orchidinae are essentially glabrous; anticlinal walls of foliar epidermal cells arc basically straight-sided to curvilinear, and cells arc fundamentally polygonal on both surfaces; adaxial cells are larger than abaxial cells. Stomata arc anomocytic and usually only abaxial and superficial; substomatal chambers are small to moderate; outer and inner guard cell ledges are mostly small. There is no hypodermis nor are there fibre bundles. Mesophyll is homogeneous, chlorcnchyma cells arc thin-walled, and intercellular spaces numerous. Crystalliferous idioblasts abound. Vascular bundles are collateral, organized in a single series. and lack associated sclerenchyma. Bundle sheath cells are thin-walled and chlorophyllous. Stems are glabrous; stomata arc frequent in one species, lacking in others. Cortical cells are oval to circular, thick-walled, and interspersed with triangular intercellular spaces. Ground-tissue cells are circular, and triangular intercellular spaces are present. Vascular bundles arc collateral and scattered throughout the ground-tissue or are absent from the central ground-tissue. Epidermis in absorbing roots is one-layered and non-velamcntous. Exodcrmal cells are thin-walled and dead cell walls bear tenuous scalariform bars; some species lack an exodermis. Outer cortical cells are polygonal and lack intercellular spaces; middle layer cortical cells are rounded with triangular intercellular spaces; inner layer cells are polygonal and lack intercellular spaces. Endodermis and pericycle are thin-walled and one-layered. Vascular cylinder is mostly 7–9-arch with xylcm and phloem components alternating regularly; vascular tissue is embedded in parenchyma; pith cells are parenchymatous, polygonal, thin-walled and lack intercellular spaces. Root tubers generally bear a velamen of variable thickness; bulbous-based unicellular hairs frequently form a dense mat; exodermal cells are thin-walled; dead cells have scalariform bars, passage cells are sparse. Ground-tissue consists of rounded water-storage and assimilatory cells interspersed with triangular or quadrangular intercellular spaces; peripheral cells arc polygonal lacking intercellular spaces. Vascular tissue consists of monarch to pentarch meristeles distributed thoughout the ground-tissue each surrounded by a uniscriale endodermis of thin-walled cells. Thin roots ofPlalanthera exhibit a typical central cylinder surrounded by a homogeneous cortex uninterrupted by meristeles; thicker roots show a central vascular cylinder and cortex in which meristeles are also present; in globoid root tubers there is no central cylinder, and the ground-tissue is replete with scattered meristeles. Because the central vascular cylinder in Platanthera gives rise to branches (meristeles), these represent components of a single vascular system and are not separate stelar entities as implied by the use of the term ‘polystele’.     

ROOTS OF SOBRALIA MACRANTHA (ORCHIDACEAE): STRUCTURE AND FUNCTION OF THE VELAMEN-EXODERMIS COMPLEX

Roots of Sobralia macrantha, a largely terrestrial orchid, bear a typical multilayered velamen underlaid by a cortical exodermis. The latter consists of densely cytoplasmic passage cells regularly interspersed among much larger, elongate, vacuolate cells. A structure which may be peculiar to Sobralia, or at least unusually well developed there—the fibrous body—consists of numerous intermeshed and divided wall outgrowths arising from two or three velamen cells positioned directly over the passage cell. This body is well designed to retard root transpiration. Should the fibrillar components be appropriately hygroscopic, it may act as a valve, promoting movements of water into the cortex while the velamen is engorged. The general mode of moisture and mineral procurement proposed for the Sobralia macrantha root probably applies to many other soil- and canopy-dwelling orchids with a velamen-exodermis complex.     

卡特兰与丝核菌共培养体系的建立及卡特兰菌根显微结构的研究*

用3个分离自野生卡特兰的丝核菌菌株接种卡特兰组培幼苗,对幼苗生长有不同程度的促进作用,处理苗的鲜重增长率(%)分别是67.5、67.3和62.4,而不接菌的对照仅为49.5,其中KW214菌株处理苗与对照差异达显著水平(α=0.05)。接菌处理后植株的N、P、K含量没有明显增加。在三个接菌处理苗的营养根中均分离获得了原接种真菌,并观察了接种KW214菌株的卡特兰营养根。真菌先侵入根被组织,经通道细胞最后侵染皮层组织细胞,并通过菌丝穿越细胞壁不断地向内延伸扩展。菌丝在皮层组织细胞内形成大量着色较深形状不规则的菌丝结等兰科菌根典型结构,菌丝结在皮层组织中分布不均,多出现在靠外侧的几层皮层细胞内,在被侵染的细胞中,菌丝结常出现在细胞核附近。菌丝结、针状晶体和细胞核在形态和着色反应上有明显区别。菌丝结和细胞核常常相互靠近。从生物量增长、显微结构、重分离接种菌株等三个方面获得的证据表明,已成功建立了卡特兰组培幼苗和丝核菌KW214的共培养体系。     

Vegetative anatomy of subtribe Habenariinae (Orchidaceae)

Leaves of Habenariinae are characterized by anomocytic stomatal apparatuses, homogeneous mesophyll, collateral vascular bundles in a single series, and thin-walled bundle sheath cells. There is no foliar sclerenchyma nor a hypodermis. Cauline cortex consists of thin-walled living cells among which are large and numerous intercellular spaces. The ground tissue is bordered externally by a layer of thick-walled living cells, except in Habenaria repens. Central ground tissue cells are living, and usually thin-walled surrounding intercellular spaces of various dimensions. These are conspicuously large in H. repens. Collateral vascular bundles are scattered across the ground tissue. Sclerenchyma is absent. Absorbing roots are generally velamentous, exodermal dead cells are diin-walled, and passage cells usually have a thickened outer wall. A regular vascular cylinder is present, and vascular tissue is embedded in parenchyma. Root tubers are velamentous, exodermal cells are usually thin-walled, and passage cells frequently have thickened outer walls. Vascular tissue of root tubers is organized into two classes: (1) those with a single vascular cylinder surrounded by a cortex and (2) those with a series of meristeles dispersed throughout the ground tissue. In group (1) cortex is homogeneous either with or without mucilage cells except in Stenoglattis where the cortex is heterogeneous, consisting of water-storage and assimilatory cells, and lacks mucilage cells. In group (2) the ground tissue consists of larger mucilage-containing cells and smaller assimilatory cells.     

Cortical cell death, cell proliferation, macromolecular movements and rTip1 expression pattern in roots of rice (Oryza sativa L.) under NaCl stress

The mode of action of NaCl in terms of cell proliferation and cell death was examined in seminal roots of rice plants (Oryza sativa L.). Salt/sodium chloride was inhibitory to cell number increase and to cell death in cortical tissue, whereas final cortical cell size was the same as in control roots that were not exposed to NaCl. It seems that NaCl may stimulate the transition phase from cell division to cell elongation. Further analysis of the role of NaCl in the suppression of cortical cell death was confined to a delay in the early stage of cell collapse, which was caused by tonoplast disruption, and plasma-membrane destruction. Sodium chloride did not have any effect on the cell-to-cell movement of macromolecules in the root cortex. In-situ hybridization studies indicated that expression of the gene for tonoplast intrinsic protein (rTip1) was localized predominantly in the epidermal and exodermal cells as well as in metaxylem cells in seminal roots. Upon NaCl treatment, the intensity of rTip1 gene expression was raised in the cortical parenchyma, suggesting that salt plays a role in the rapid onset of cell elongation. Received: 2 April 1998 / Accepted: 18 September 1998     

附生兰科植物根被组织研究概述

植物根被组织是指存在于附生兰科植物、地生兰科植物、一些石蒜科、天南星科、薯蓣科以及百合科植物根部的典型适应性结构特征;成熟根被组织是由1～25层左右死细胞构成的白色鞘,其细胞壁多有螺旋式增厚,呈天鹅绒状或网状、羽毛状结构,具有海绵质地.该组织有六种应用于分类学特征的形态,依据这六种形态可将其分为12种类型;根被组织具有...