兰科植物与菌根真菌的营养关系

兰科植物与真菌具有天然的菌根共生关系。兰科植物种子细小,无胚乳,自然条件下只有与适宜的真菌共生才能萌发;兰科植物作为有花植物中最大的科之一,有光合自养、混合营养及完全真菌异养等营养类型。近年研究表明,不同营养类型的兰科植物其菌根真菌常具有一定的差异性,表现出不同的营养作用关系。本文对不同营养类型兰科植物与菌根真菌的营养作用关系的研究进展进行综述,并对兰科植物菌根营养机理、营养关系的变化等进行讨论,以期为兰科菌根营养学研究及菌根技术应用于兰科植物快繁和保育工作等提供参考。     

兰科药用植物手参种子的真菌共生萌发

手参Gymnadenia conopsea是一种地生型兰科植物,是我国的传统中药,同时也是蒙药、藏药常用药,在西藏地区亦作食用。现代药理学研究表明手参具有非常好的药理活性,然而当前手参还不能进行人工栽培,市场需求完全依赖野生资源,因此资源短缺仍然是制约该种药用植物进一步开发利用的瓶颈。兰科植物种子萌发及早期的幼苗生长均需真菌参与,基于此,本文从手参根系中进行了真菌分离,并获得一株菌株,分子鉴定为角担菌属Ceratobasidium GS2。将GS2菌株与手参种子进行共培养,可明显促进手参种子的原球茎的形成并最终分化成幼苗。手参种子共生萌发的成功对于实现手参的种质保育、人工栽培和野生居群的生态恢复均具有重要的意义。     

兰科植物共生胶膜菌:分类学、多样性、专一性和适应性

兰科植物与丝核菌类真菌,包括胶膜菌科、角担菌科和蜡壳菌科等形成菌根共生体。胶膜菌科真菌作为最广泛分布的共生菌根真菌,表现出与兰科植物的协同进化与密切关系。除了形态学特征分析和比较外,分子技术促进了兰科植物胶膜菌的分类学和多样性研究。兰科植物与胶膜菌的特异性可能限制兰科植物的分布和移栽后的生存能力,但有些兰科植物与胶膜菌的共生关系会因为地理分布或环境变化进行调整,使植物更好地生存,这种适应性为实现无菌苗菌根化来促进兰科植物的迁地保护或繁殖提供可能。本文综述了兰科植物共生菌根真菌胶膜菌在分类学、多样性、特异性和适应性等方面的研究。     

真菌在兰科植物种子萌发生长中的作用及相互关系

本文从真菌在兰科种子萌发中的应用、真菌侵染的过程、种子和根系消化真菌的途径及共生真菌的分布等方面,综述了真菌与兰科植物种子萌发及菌根关系的研究进展,讨论了该研究的有关问题及真菌在兰科种子萌发中应用的前景。     

兰科杓兰属（Cypripedium）植物种子非共生萌发研究进展

兰科杓兰属(Cypripedium)植物主要分布于东亚、北美等温带地区和亚热带山地。杓兰不仅具有极高的观赏价值,而且其经济价值和科研价值也越来越受到人们的重视。近年来对杓兰属植物人工繁殖的相关研究不断深入,主要集中于种子的非共生萌发等方面。本文对濒危兰科杓兰属植物进行了简要介绍,并就其种子非共生萌发研究从种子成熟度、预处理和有机添加物的作用、培养基的配置等方面进行综述,为目标杓兰种类的非共生萌发试验方案的制定奠定基础,将有助于温带/高山兰科植物保育研究的发展。     

真菌在兰科植物种子萌发生长中的作用及相互关系

本文从真菌在兰科种子萌发中的应用、真菌侵染的过程、种子和根系消化真菌的途径及共生真菌的分布等方面,综述了真菌与兰科植物种子萌发及菌根关系的研究进展,讨论了该研究的有关问题及真菌在兰科种子萌发中应用的前景。     

内生真菌对兰科药用植物种子萌发作用研究进展

兰科植物种子细小,无胚乳,自然条件下需与适宜的内生真菌共生才能萌发。近年来,大量研究结果表明,内生真菌能够为兰科药用植物种子萌发提供必要的碳源、氮源等多种营养物质。本文对内生真菌为兰科药用植物种子提供的营养物质进行总结,并对二者的营养关系进行了综述。     

硬叶兰种子的迁地共生萌发及有效共生真菌的分离和鉴定

兰科植物的种子原地和迁地共生萌发技术是近年发展起来的开展兰科植物种子和共生真菌研究的有效方法。该研究对兰属(Cymbidium)附生植物硬叶兰(C. mannii)开展了种子的迁地共生萌发研究, 试图获得其种子萌发的有效真菌。利用硬叶兰成年植株根部周围的树皮、苔藓、枯枝落叶、腐殖质等作为培养基质, 进行种子的共生培养。在培养133天后, 成功地获得了处于不同阶段的已萌发种子、原球茎和幼苗, 并从原球茎中分离得到一种瘤菌根菌属(Epulorhiza)真菌。用所分离到的FCb4菌株和一种从兜唇石斛(Dendrobium aphyllum)分离到的胶膜菌属(Tulasnella) FDaI7菌株和硬叶兰种子在燕麦琼脂培养基上进行共生萌发, 设置不接菌作为对照处理, 以检验FCb4菌株对硬叶兰种子萌发的有效性。经过58天的培养, 不接菌的对照处理中种子没有萌发, 接种FCb4和FDaI7菌株的处理都有很高的种子萌发率, 两种接菌处理在不同光照条件下的种子萌发率均无显著性差异。但暗培养条件下, 种子萌发形成原球茎后, 表现出生长停滞的趋势, 仅有很少的原球茎继续生长达到幼苗阶段, 说明原球茎发育后期与幼苗发育阶段需要光照。在光照条件下, 接种FCb4菌株处理中达到幼苗阶段种子的比例为(25.67 ± 9.27)%, 显著高于接种FDaI7菌株处理的(3.04 ± 2.27)% (W = 56, p = 0.026, Mann-Whitney U-test), 表明此研究中分离到的瘤菌根菌属真菌能有效地促使硬叶兰种子萌发并生长发育到幼苗阶段。     

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。     

共生真菌对兰科植物种间杂交后代种子萌发的效应

石斛属(Dendrobium)植物在种子共生萌发过程中与真菌有着较为专一的共生关系,为探讨这种共生关系在种间杂交后代上的进化和适应,深入理解兰科植物和真菌共生关系的形成机制,该研究利用能有效促进铁皮石斛(Dendrobium officinale)和齿瓣石斛(D.devonianum)种子萌发形成幼苗,并具有较强专一性的胶膜菌属(Tulasnella)真菌SSCDO-5和瘤菌根菌属(Epulorhiza)真菌FDd1,开展真菌对铁皮石斛和D. tortile种间杂交种子萌发效应的研究。结果表明,在真菌与种子共生培养68天时,SSCDO-5菌株和FDd1菌株都能有效地促进杂交种子形成原球茎和幼苗,两个接菌处理之间无显著差异,来源于铁皮石斛的SSCDO-5菌株不但没有表现出优势,反而在杂交石斛幼苗形成率上低于来源于齿瓣石斛的FDd1菌株(SSCDO-5:(22.13±6.62)%; FDd1:(29.53±5.51)%); SSCDO-5菌株和铁皮石斛在幼苗形成和发育阶段的共生专一性并没有在杂交后代上得到遗传或表现,或者说是杂交打破了这种专一性的共生关系,使得杂交后代能够和不同的真菌建立新的共生关系。该结果不支持关于共生真菌专一性是石斛属植物杂交后代形成的重要限制因素的假设,推测石斛属植物在幼苗分化和发育阶段与真菌这种专一性的共生关系是在适应特定生态环境的过程中形成和建立的。     

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。     

Variation in mycorrhizal performance in the epiphytic orchid <Emphasis Type="Italic">Tolumnia variegata in vitro</Emphasis>: the potential for natural selection

Symbiotic seed germination is a critical stage in orchid life histories. Natural selection may act to favor plants that efficiently use mycorrhizal fungi. However, the necessary conditions for natural selection – variation, heritability, and differences in fitness – have not been demonstrated for either orchid or fungus. With the epiphytic orchid Tolumnia variegata as a model system, we ask the following questions: (1) Do seeds from different individuals in a population differ in germination and seedling development in the presence of the same fungi? (2) Do different mycorrhizal fungi (Ceratobasidium spp.) differ in ability to stimulate seed germination and growth in T. variegata? And (3) are the Ceratobasidium isolates that best induce seed germination and seedling development more closely related to each other than to isolates that are less effective? We performed symbiotic seed germination experiments in vitro. The experiments were done using mycorrhizal fungi isolated from T. variegata; relationships among the fungi were inferred from nuclear ribosomal ITS sequences. We found significant variation for both symbiotic germination and seedling growth among biparental seed crops obtained from a population of T. variegata plants. Differences among Ceratobasidium fungi in seed germination were significant. The fungi that induced highest seed germination and seedling development belonged to two of four clades of Ceratobasidium. The two experiments show that there is potential for natural selection to act on orchid–fungus relationships. Given that orchids vary in performance, and that mycorrhizal fungi are not geographically distributed homogeneously, mycorrhizae may affect population size, distribution and evolution of orchids.     

Endophytic fungi from Pecteilis susannae (L.) Rafin (Orchidaceae), a threatened terrestrial orchid in Thailand

Eight endophytic fungi were isolated from roots of the threatened terrestrial orchid, Pecteilis susannae (L.) Rafin. Phylogenetic analysis based on an alignment of internal transcribed spacer regions of nuclear rDNA indicated that seven isolates belonged to the genus Epulorhiza and one to Fusarium. All fungal isolates were cultured with orchid seeds collected from three field sites near Doi Suthep-Pui National Park, Chiang Mai, Thailand. Seed germination and protocorm development were evaluated up to 70 days after sowing. Percent symbiotic seed germination was highest (86.2%) when seeds were cultured with Epulorhiza (CMU-Aug 013). The protocorm development was the most advanced up to stage 2, continued embryo enlargement, or rupture of the testa, and the highest percentage was 17.8% when seeds were cultured with Epulorhiza (CMU-Aug 007). Without fungi, seed germination and protocorm development were 62.1% and 11.1%, respectively. The dependency of P. susannae on fungal symbionts for early seedling development is yet to be determined. Optimizing seed germination and seedling fitness will assist the conservation of this threatened orchid in Thailand.     

Symbiotic seed germination of Habenaria macroceratitis (Orchidaceae), a rare Florida terrestrial orchid

The rapid loss of native orchid habitat throughout ecologically important areas (e.g., Florida) has prompted researchers to develop appropriate plans for the propagation and reintroduction of many native orchid species. Ideally, symbiotic orchid seed germination methods are utilized in the production of orchid seedlings to be used in plant reintroduction programs. In the current study we (1) describe an efficient symbiotic seed germination protocol to germinate seeds of the rare sub-tropical terrestrial orchid Habenaria macroceratitis; (2) discuss the in vitro fungal specificity demonstrated by this species; and (3) describe the effects of three photoperiods (0/24 h, 16/8 h, 24/0 h L/D) on in vitro symbiotic seed germination of H. macroceratitis. Six fungal mycobionts were isolated from both vegetative and flowering plants of H. macroceratitis from two geographically distinct sites. Symbiotic seed germination percent was highest (65.7%) and protocorm development was most advanced (Stage 2) when seeds were cultured with fungal mycobiont Hmac-310. Seeds of H. macroceratitis demonstrated a degree of specificity toward fungal mycobionts isolated from plants originating from the same site where seed was collected. Continual darkness (0/24 h L/D) inhibited initial seed germination (Stage 1; 17.1%), but stimulated subsequent protocorm development (Stage 2; 53.5%). These findings will aid in developing an efficient symbiotic seed germination protocol for the conservation of this rare Florida terrestrial orchid, and may prove useful in the conservation of other sub-tropical terrestrial orchid species.     

带叶兜兰种子原地共生萌发及有效菌根真菌的分离与鉴定

为获得带叶兜兰(Paphiopedilum hirsutissimum)种子萌发的共生真菌,采用原地共生萌发技术获得了2株自然萌发的小幼苗,并分离和筛选出了有效的种子萌发共生菌——瘤菌根菌(Epulorhiza sp.)。为验证分离菌株对带叶兜兰种子萌发的有效性,将Phs34号菌株与带叶兜兰种子在灭菌后的原生境基质上进行室内共生萌发试验,结果表明,经过6周的培养,对照组没有观察到种子的萌发;接菌的种子胚明显膨大,突破种皮,形成原球茎,平均萌发率为(58.35±3.41)%。这表明分离得到的瘤菌根菌能促进带叶兜兰的种子萌发。     

Impacts of Host Trees and Sowing Conditions on Germination Success and a Simple Ex Situ Approach to Generate Symbiotic Seedlings of a Rare Epiphytic Orchid Endemic to Hainan Island,China

For species relying on seeds for population regeneration, knowledge on seed germination behaviors in relation to environmental factors is critical in designing species recovery strategy. Dendrobium sinense is an orchid endemic to Hainan Island of China and listed as Endangered by the IUCN Redlist. It reproduces primarily via seeds in its natural habitat. However, how germination is impacted by major environmental factors is poorly known. This study aimed to examine germination success of D. sinense seeds using two approaches, i.e. in situ and ex situ, using host tree barks as germination media. The latter was intended to generate symbiotic seedlings in a simple and economic approach which could be used for reintroduction efforts. In addition, three factors of in situ symbiotic seed germination success, including different sowing time, location (distance from an adult plant), and host tree were investigated. Our results showed that seeds sown ex situ and in situ in July had the highest rates of germination. Seed germination was significantly higher ex situ using bark as medium than in situ. Seeds sown directly on Rhododendron moulmainense, the most common host tree, with naturally occurring conspecific orchids had the highest rate of germination. In contrast, ex situ seeds sown on the bark of Cyclobalanopsis blakeii, a non-host species, had the highest rate of seed germination. In situ a positive correlation was found between the seed germination rate and the distance of the seeds from the adult D. sinense. Based on these results, it is likely seedling recruitments are determined by host tree species, the presence of and the distance from an adult conspecific orchid, which imply the importance of the mycorrhizal fungi, which were not reported here. This study provided important information on the optimal environmental conditions for population augmentation and reintroduction, which can be used as part of the species recovery strategy.     

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.     

In situ seed baiting to isolate germination-enhancing fungi for an epiphytic orchid,Dendrobium aphyllum (Orchidaceae)

Orchid conservation efforts, using seeds and species-specific fungi that support seed germination, require the isolation, identification, and germination enhancement testing of symbiotic fungi. However, few studies have focused on developing such techniques for the epiphytes that constitute the majority of orchids. In this study, conducted in Xishuangbanna Tropical Botanical Garden, Yunnan, China, we used seeds of Dendrobium aphyllum, a locally endangered and medicinally valuable epiphytic orchid, to attract germination promoting fungi. Of the two fungi isolated from seed baiting, Tulasnella spp. and Trichoderma spp., Tulasnella, enhanced seed germination by 13.6 %, protocorm formation by 85.7 %, and seedling development by 45.2 % (all P?Epulorhiza, another seed germination promoting fungi isolated from Cymbidium mannii, also enhanced seed germination (6.5 %; P?P?Trichoderma suppressed seed germination by 26.4 % (P?Tulasnella was the only treatment that produced seedlings. Light increased seed imbibition, protocorm formation, and two-leaved seed development of Tulasnella inoculated seeds (P?Tulasnella be introduced for facilitating D. aphyllum seed germination at the protocorm formation stage and that light be provided for increasing germination as well as further seedling development. Our findings suggest that in situ seed baiting can be used to isolate seed germination-enhancing fungi for the development of seedling production for conservation and reintroduction efforts of epiphytic orchids such as D. aphyllum.     

铁皮石斛种子的室内共生萌发

由于人为的采挖和原生境的破坏,使得铁皮石斛野生资源已濒临灭绝。因此,保护铁皮石斛野生资源及其生境,加快其野生资源的繁殖显得非常重要。以铁皮石斛种子(TTC染色显示种子生活力为77.65%)为材料,与分离自2种野生兰科植物根部的4株共生真菌 (C20来自铁皮石斛,L12,L24b 和 L28来自美花石斛)在燕麦培养基上进行共生萌发。经过18周的共生培养,4株真菌均不同程度地促进了铁皮石斛种子的萌发,其中菌株L24b (Epulorhiza)和L28 (Epulorhiza)显著提高了种子的萌发率,分别比对照高出26.51%和12.20%,但未形成幼苗,只是处于原生分生组织阶段(阶段3);菌株C20(Epulorhiza)和L12 (Alternaria) 虽没有显著提高种子的萌发率,但对原球茎的发育和幼苗的生长有明显的促进作用;而对照的种子仍然处于膨大转绿期,即萌发阶段(阶段2)。同时发现,TTC染色显示的铁皮石斛种子生活力要高于种子共生萌发的萌发率(除了菌株L24b)。研究结果表明:种子生活力染色检测的活力值只代表种子所具有的潜在的萌发能力,而不能代表实际的萌发率。在异地条件下,铁皮石斛与共生真菌间没有严格的专一性,可以与瘤菌根菌属、链格孢属真菌形成共生关系。菌株C20和L12能促进萌发后的种子进一步分化成幼苗。这两个菌株为铁皮石斛的人工优质栽培和野外种群的建立提供了可能。