天麻种子／原球茎和营养繁殖茎被菌根真菌定殖后的细胞分化

天麻（Gastrodia elata Bl.)种子可与紫萁小菇（Mycena osmundicola Lange),兰小菇（M.orchidicola Fan et Guo)等一类小菇属真菌共生萌发形成原球茎。侵入种皮的菌丝集结在柄状细胞外周的胚柄残迹中,首先侵入胚的柄状细胞,然后自柄状细胞侵入其他原胚细胞。原胚细胞发生功能分化,形成菌丝结细胞和消化细胞,初被菌丝定殖的原胚细胞具有消化菌丝的功能,随后,部分原胚细胞逐渐被菌丝充满,充育成菌丝结细胞。菌丝由菌丝结细胞进一步侵入消化细胞后最终被消化。由原球茎分化形成的营养繁殖茎（以下简称营繁茎）进一步被蜜环菌（Armilariella mellea(Vahl.Fr.)Karst.)定植,蜜环菌与紫箕小菇的菌丝同时存在于营繁茎中,但两菌相遇时都停止蔓延,互不交错侵染。     

天麻种子与兰小菇共生萌发过程中超微结构变化研究*

天麻Ｇａｓｔｒｏｄｉａｅｌａｔａ种子与兰小菇Ｍｙｃｅｎａｏｒｃｈｉｄｉｃｏｌａ的共生萌发试验表明兰小菇可与天麻种子共生促进天麻种子萌发并形成原球茎。菌丝自胚柄端的柄状细胞侵入天麻种子原胚,其分布被限制在天麻原球茎基部的柄状细胞、外皮层细胞和内皮层细胞内,均被电子透明物质和原球茎细胞质膜包围而与原球茎细胞质相隔离。菌丝在外皮层细胞中形成菌丝结,在内皮层细胞中则被消化,形成扁化、衰败的菌丝或菌丝四块。含有衰败菌丝的原球茎细胞可被菌丝重新定殖,新近定殖的菌丝又被原球茎细胞消化。     

天麻种子与兰小菇共生萌发过程中超微结构变化研究

天麻Ｇａｓｔｒｏｄｉａｅｌａｔａ种子与兰小菇Ｍｙｃｅｎａｏｒｃｈｉｄｉｃｏｌａ的共生萌发试验表明兰小菇可与天麻种子共生促进天麻种子萌发并形成原球茎。菌丝自胚柄端的柄状细胞侵入天麻种子原胚,其分布被限制在天麻原球茎基部的柄状细胞、外皮层细胞和内皮层细胞内,均被电子透明物质和原球茎细胞质膜包围而与原球茎细胞质相隔离。菌丝在外皮层细胞中形成菌丝结,在内皮层细胞中则被消化,形成扁化、衰败的菌丝或菌丝四块。含有衰败菌丝的原球茎细胞可被菌丝重新定殖,新近定殖的菌丝又被原球茎细胞消化。     

天麻种子萌发过程与开唇兰小菇的相互作用*

实验表明开唇兰小菇Mycena anoectochila可与天麻Gastrodia elata种子共生促进其萌发形成原球茎。 菌丝自胚柄端的柄状细胞侵入天麻种子原胚,进一步在皮层细胞中扩展,在外皮层细胞中形成发育良好的菌丝结,菌丝完整而有活力; 在内皮层细胞中则被消化,菌丝衰败、扁化。菌丝在原球茎细胞内的分布被限制在原球茎基部的柄状细胞、外皮层细胞和内皮层细胞,菌丝均被电子透明物质包围, 外围环绕有原球茎细胞质膜, 该界面使侵入的菌丝与原球茎细胞质相隔离,也是两共生生物间进行物质交换的所在。上述菌丝侵入至被消化的过程在整个原球茎发育过程中可反复进行。     

天麻种子萌发过程与开唇兰小菇的相互作用

实验表明开唇兰小菇Mycena anoectochila可与天麻Gastrodia elata种子共生促进其萌发形成原球茎,菌丝自胚柄端的柄状细胞侵入天麻种子原胚,进一步在皮层细胞中扩展,在外皮层细胞中形成发育良好的菌丝结,菌丝完整而有活力;在内皮层细胞中则被消化,菌丝衰败,扁化,菌丝在原球茎细胞内的分布被限制在原球茎基部的柄状细胞,外皮层细胞和内皮层细胞,菌丝均被电子透明物质包围,外围环绕有原球茎细胞质膜,该界面使侵入的菌丝与原球茎细胞质相隔离,也是两共生生物间进行物质交换的所在,上述菌丝仞入至被消化的过程在整个原球茎发育过程中可反应进行。     

应用放射性自显影技术研究标记紫萁小菇侵染天麻种胚的过程

用~3H—葡萄糖对紫萁小菇进行氚标记,然后用标记的紫萁小菇伴播天麻种子,发现标记紫萁小菇在侵入天麻胚柄状细胞后,菌丝即被溶解、消化,未被侵染的大型细胞中有标记化合物的踪迹。随着胚的发育,在胚顶端分生细胞中也有大量标记物的显影银粒云集,表明同化的标记化合物由细胞壁进入并通过胞间连丝进行运输,直观证明了紫萁小菇为天麻种子萌发提供了营养。     

应用放射性自显影技术研究标记紫萁小菇侵染天麻种胚的过程

用＾３Ｈ－葡萄糖对紫萁小菇进行氚标记,然后用标记的紫萁小菇伴播天麻种子,发现标记姑在侵入天麻胚柄状细胞后,菌丝即被溶解,消化,未被侵染的大型细胞中有标记化合物的踪迹,随着胚的发育,在胚顶端分生细胞中也有大量标记物的显影银粒云集,表明同化的标记化合物由细胞壁进入并通过胞间连丝进行运输,直观证明了紫萁小菇为天麻种子萌发提供了营养。     

天麻种子萌发过程中与其共生真菌石斛小菇间的相互作用

天麻Ｇａｓｔｒｏｄｉａ ｅｌａｔａ种子与石斛小菇Ｍｙｃｅｎａ ｄｅｎｄｒｏｂｉｉ的共生萌发试验表明,石斛小菇可与天麻共生,促进天麻种子发芽并形成原球茎。菌丝主要分布于原球茎的柄状细胞、外皮层细胞和内皮层细胞,在外皮层细胞中形成菌丝结,内皮层细胞中的菌丝则被消化。原球茎细胞中的菌丝均被电子透明物质和原球茎细胞质膜包围而与球茎细胞质相隔离,菌丝进一步液泡化并最终被水解。含有衰败菌丝的原球茎细胞常被菌丝     

天麻种子萌发过程中与其共生真菌石斛小菇间的相互作用

天麻Gastrodiaelata种子与石斛小菇Mycenadendrobii的共生萌发试验表明,石斛小菇可与天麻共生,促进天麻种子发芽并形成原球茎。菌丝主要分布于原球茎的柄状细胞、外皮层细胞和内皮层细胞,在外皮层细胞中形成菌丝结,内皮层细胞中的菌丝则被消化。原球茎细胞中的菌丝均被电子透明物质和原球茎细胞质膜包围而与原球茎细胞质相隔离,菌丝进一步液泡化并最终被水解。含有衰败菌丝的原球茎细胞常被菌丝重新定殖。这一菌丝被消化及菌丝的重新定殖过程在整个原球茎发育过程中可不断重复发生。     

天麻种子萌发过程中与其共生真菌石斛小菇间的相互作用*

天麻Gastrodiaelata种子与石斛小菇Mycenadendrobii的共生萌发试验表明,石斛小菇可与天麻共生,促进天麻种子发芽并形成原球茎。菌丝主要分布于原球茎的柄状细胞、外皮层细胞和内皮层细胞,在外皮层细胞中形成菌丝结,内皮层细胞中的菌丝则被消化。原球茎细胞中的菌丝均被电子透明物质和原球茎细胞质膜包围而与原球茎细胞质相隔离,菌丝进一步液泡化并最终被水解。含有衰败菌丝的原球茎细胞常被菌丝重新定殖。这一菌丝被消化及菌丝的重新定殖过程在整个原球茎发育过程中可不断重复发生。     

Cytodifferentiation of the Seeds (Protocorms) and Vegetative Propagation Corms Colonized by Mycorrhizal Fungi

The stipecell, subepidermal parenchyma cells and inner cortical parenchyma cells were differentiated from Gastrodia elata Bl. seed and protocorm cells when they were colonized by the fungal hyphae of Mycena osmundicola Lange and M. orchidicola Fan et Guo. The hyphae aggregated in the suspensor remnant surrounding stipecell, primarily penetrated the stipecell, and then colonized the embryo of seed. Stipecell is the unique invading site of the hyphae. Subepidermal parenchyma cells containing pelotons of hyphae is also a kind of passage cells of hyphae, but, when primarily colonized by hyphae, they can degenerate a little of hyphae. The hyphae colonizing inner cortical parenchyma cells were totally degenerated, and the function of inner ocrtical parenchyma cells is digestive. The vegetative propagation corms, which differentiated from protocorms, were recolonized by Armilariella mellea (Vahl:Fr.) Karst., and the hyphae of A. mellea and M. osmundicola were found in the same cell, but there is a layer of cells uncolonized by mycorrhizal fungal hyphae. This means the two fungal species can not crisscross colonize the cell of G. elata.     

猪苓与蜜环菌的关系

蜜环菌Armilla riella mcllea(Vahl：Ff．)Kgtst·侵入猪苓Gri[ola umbe』zd‘4(PetsFr．)PilOt)菌核,激活了猪苓菌抵御异体侵染免疫反应的本能,猪苓菌丝细胞木质化,形成与菌核表皮结构相似的隔离腔,将蜜环菌素和部分猪苓菌丝包围。在隔离腔中蜜环菌消化分隔在腔中的猪苓菌丝,另外猪苓菌丝也可侵入或附着在蜜环菌索及侵染带细胞间隙吸收其代谢产物,猪苓菌核即可萌发出新苓正常生长。当隔离腔中的猪苓菌丝被消化后,蛮环菌生活力也减弱,解体后被猪苓菌吸收利用,隔离腔变成空腔。从广义角度看,仍可把蜜环菌与猪苓菌寄生与反寄生的营养关系概括为共生关系。     

The Relation Between Growth of Gastrodia elata Protocorms and Fungi

Armillaria mellea penetrated protocorms from seed germination and vegetative multiplication corms of Gastrodia elata with rhizomorph. At beginning, they formed a hypha passing road and a hypha flow in the inner cells of cortex, and then, they both penetrated inside of large cells and penetrated outside of cortical cells. Gastrodia elata seeds depended on digesting Mycenct osmundicola etc gain nutrition to germinate at the stage of sexual reproduction, but its corms of vegetative multiplication must be penetrated by Armillaria mellea obtaining nutrition for normal growth at the stage of vegetative propagation.     

天麻中抗真菌蛋白质的诱导和积累

前曾报告从天麻（Ｇａｔｒｏｄｉａ ｅｌａｔａ Ｂｌ）中分离出一种对木霉丝生长有强抑制作用的蛋白质,命名为天麻抗真菌蛋白,简称ＧＡＦＰ,也称为Ｇａｓｔｒｏｄｉａｎｉｎ。对不同天麻材料来源的ＧＡＦＰ分析表明：ＧＡＦＰ的相对分量为１４ｋＤ,等电点可能不同,变动范围８．１－９．３。体外抑菌试验证明ＧＡＦＰ对腐生性真菌如木霉如木霉和密环菌等有强抑制活性,半抑制浓度ＩＣ０．５为０．０８ｍｇ／ｍＬ;对寄生免疫荧     

Studies on the Character istic of the Structures in the Cortical Cells of Gastrodia clara after Infection of Armillaria mellea

Aided by the techniques of thin and ultrathin sectioning and electron microscopy, the characteristic of structures in the cortical cells of Gastrodia elata was further investigated after infection of Armillaria mellea. It was found that the “hyphal coils”, observed with light microscope, in the cortical cells of G. elata were saccate structures deriv- ed from the cytoplasm of cortical cells and enclosed hyphae. And the cell walls of hyphae were digested in these sacs. Then, these hyphae without cell wall were cut into protoplast fragments in inner-most cortical cells. The results indicated that the cortical cells of G. elata possess digestive function.     

Nutrient Source of Sclerotia of Grifola umbellata and Its Relationship to Armillaria mellea

Ways nutrient-uptake of sclerotia of Grifola umbellata and the relationship between G. umbellata and Armillaria mellea were studied. At the primary stage of sclerotia of G. umbellate infected by A. mellea, the hyphae of G. umbellata could obtain nutrients by invading the one- to three-layer-cells of A. mellea cortex which existed in the sclerotia of G. umbellata, ar late stage of A. mellea infection, the nutrient source of sclerotia of G. umbellata mainly depended on its hyphae, adhering on the intercellular space of A. mellea, to suck the metabolic products of A. mellea. After being nourished the hyphae of sclerotia of G. umbellata outside of the rhizomorph of A. mellea began to reproduce, as their nuclear divisions were well observed. The results suggested that the mutual assimilation between G. umbellata and A. meIlea could be defined as a form of special Symbiotic relation.     

Study on Ultrastructure and Localization of Acid Phosphatase of Gastrodia elata Cortical Cells in Their Digestive Process of Armillaria mellea

In order to study the mechanism of the digestive process of Armillaria mellea in Castrodia data, electron microscopy and cytochemical method for determination of acid phosphatase activity was employed. The provacuoles were formed by means of expanded or convoluted ER under the stimulation of cortical cells and large cells of Gastrodia data by Armillaria mellea. A product of acid phosphatase (lead phosphate deposits) occured on the tonoplast. The papillae were produced in the cell wall of cortex in Gastrodia data when Armillaria mellea penetrated into its cortex. Our results showed that the enzyme was not released from cell of Armillaria mellea. A number of small vacuoles in the cortical cells disappeared. At the same time, lead phosphate deposits on the Armillaria mellea hyphae wall were observed and than Armillaria mellea hyphae wall was going to be digested, and the hyphae lost their structure. The activity of Armillaria mellea hyphae was not observed in the large cell of Gastrodia data. A great deal of small vacuoles and mitochondria were produced, at the same time the renewable nuclei and nuclolar vacuoles etc. appeared in the large cells of Gastrodia data under the stimulation of Armillaria mellea.     

天麻吸收蜜环菌营养机制的细胞学研究

天麻(Gastrodia elata BI.)地下块茎皮层内具三种染菌细胞:通道细胞、寄主细胞和消化细胞。超微结构的研究表明,通道细胞被真菌所破坏,寄主细胞与真菌保持共生关系,而消化细胞能反寄生于真菌并从真菌摄取营养。消化细胞首先释放溶酶体小泡消化真菌,然后通过内吞管和内吞泡吸收菌丝细胞质降解后渗漏的可溶性有机大分子物质,后期通过消化泡进一步吞噬和消化不溶性菌丝细胞壁物质。