菌根真菌对白及种子萌发和幼苗生根的作用

自然条件下,兰科植物需要依赖菌根真菌获得营养才能萌发。本研究对白及根和原球茎中分离的4株菌根真菌（WQ17-33、WQ17-43、JST-3和SL15-7）进行分子鉴定,并评价光照和黑暗条件下不同菌株促白及种子萌发和幼苗生根的效果。结果表明,4个菌株分别隶属于鬼伞属Coprinus、胶膜菌属Tulasnella、腊壳菌属Sebacina和Serendipita。在种子萌发前期（未形成叶子）进行暗培养较光照对菌株JST-13和SL15-7处理组原球茎阶段萌发具有显著的促进作用。不同菌株共生萌发效果不同,菌株SL15-7较其他处理原球茎和幼苗发育阶段的萌发率高。菌株JST-13和SL15-7处理组形成的幼苗较其他处理组强壮,定殖的菌丝团也较多,其幼苗生根效果也较对照组好。该研究表明白及可与多种不同类群的菌根真菌菌株形成共生关系,这些真菌在促进白及种子萌发和生根能力方面存在差异。     

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。     

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。     

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。     

不同培养基对兰科药用植物手参原球茎共生真菌的分离效果

兰科植物手参Gymnadenia conopsea作为国家二级重点保护野生植物具有重要的药用价值。目前手参还未实现人工栽培,但其种子的真菌共生萌发已获成功。为明确除促萌发真菌外,还有哪些土著真菌参与了手参种子的萌发过程,本研究在自然条件下采用促萌发真菌伴播手参种子,获得了种子萌发形成的原球茎,进而对比了6种常见的培养基PDA (马铃薯葡萄糖琼脂培养基)、MMN (改良Melin-Norkrans培养基)、FIM (真菌分离培养基)、MEA (麦芽浸膏琼脂培养基)、CAM (胡萝卜葡萄糖琼脂培养基)和CMA (玉米粉琼脂培养基)对手参原球茎共生真菌分离效果的影响。共从6种培养基上分离获得了75个菌株,其中MMN、CAM、PDA、FIM、MEA、CMA培养基依次分离得到20株、16株、15株、11株、8株、5株菌。此外,真菌的多样性分析结果表明,MMN培养基的Chao 1、Shannon-Wiener和Simpson多样性指数最高,CAM和PDA培养基次之,CMA培养基最低。综上所述,真菌分离效果最好的是MMN培养基,其次是CAM和PDA培养基,而FIM和MEA培养基对真菌的分离效果影响不大,CMA培养基的分离效果最差。本研究结果可为其他兰科植物原球茎共生真菌的分离提供借鉴,所获得的菌株也有望进一步应用于功能菌剂的研发。     

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。     

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。     

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。     

春兰菌根菌的分离及共生培养体系的研究

采用根组织切片法自野生春兰菌根共分离到6株真菌菌株,接种春兰杂交组培苗,结果发现CL-3和CL-6菌株在菌-苗共生培养基Ⅰ中对幼苗生长有不同程度的促进作用,2 个月后处理苗的鲜重增长率分别达到47.4%和42.5%,与对照差异达显著水平(P＜0.05).在CL-3和CL-6接菌处理苗的营养根中均分离获得了原接种真菌,并观察到了菌根结构.结果表明,CL-3和CL-6菌株已与组培幼苗成功建立了共生培养体系.     

兰科植物种子共生萌发真菌多样性及共生萌发机制研究进展

自然环境下,兰科植物种子细小无胚乳,需要和适宜的真菌共生才能萌发,因而与真菌有天然的共生关系。自身繁殖率低加之近年来栖息地环境破坏导致兰科植物资源更加濒危,而通过筛选适合的真菌进行种子的共生萌发可以有效地实现兰科植物的种质保育及濒危种类野生居群的生态恢复。本文对地生型、附生型以及腐生型等兰科植物已发现的萌发真菌的多样性进行了系统地梳理,发现担子菌门的胶膜菌科、角担菌科以及蜡壳耳目真菌为已报道共生萌发真菌的主要类群;同时对兰科植物种子的共生萌发机制,包括形态学机制、营养机制和分子机制等方面的相关研究进行了归纳论述,但是当前关于兰科植物和真菌互作机制方面的研究还相对较少,许多问题需要进一步明确。本文对共生萌发真菌在兰科植物保育和繁育中的应用以及共生萌发机制的研究等方面具有一定的参考价值。     

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.     

Host-specificity of symbiotic mycorrhizal fungi for enhancing seed germination,protocorm formation and seedling development of over-collected medicinal orchid, <Emphasis Type="Italic">Dendrobium devonianum</Emphasis>

All orchids maintain an obligate relationship with mycorrhizal symbionts during seed germination. In most cases, germination-enhancing fungi have been isolated from roots of mature plants for conservation and cultivation purposes. To understand the germination biology of Dendrobium devonianum, an over-collected medicinal orchid, the seeds of D. devonianum were inoculated with a fungal strain (FDd1) isolated from naturally occurring protocorms of D. devonianum and two other germination-enhancing fungal strains (FDaI7 and FCb4) from D. aphyllum and Cymbidium mannii, respectively. The fungal strain was isolated from five protocorms of D. devonianum and identified as a species of the genus Epulorhiza. In germination trials, treatments with all of the three fungal strains showed a significant promoting effect on seed germination and protocorm formation, compared with the control treatment (no inoculation). However, FDd1 fungal strain showed the greatest effectiveness followed by FDaI7 and FCb4. For all inoculation and control treatments, seeds developed to protocorms regardless of the presence of illumination, whereas protocorms did not develop to seedlings unless illumination was provided. The results of our manipulative experiments confirmed the hypothesis that mycorrhizae associated with orchid seedlings are highly host-specific, and the degree of specificity may be life stagespecific under in vitro conditions. The specific mycorrhizal symbionts from protocorms can enhance restoration efforts and the conservation of orchids such as D. devonianum.     

In vitro symbiotic seed germination of South Indian endemic orchid Coelogyne nervosa

Study on the dependence of orchids on fungi for seed germination and seedling development provides a mean for understanding the role of fungi in the orchid development process. The epiphytic orchid Coelogyne nervosa endemic to south India is exploited in an unsustainable manner for its therapeutic value. So a protocol for symbiotic seed germination was established for C. nervosa. We isolated a fungus by plating mycorrhizal root discs of the terrestrial orchid Eulophia epidendreae and identified it as Epulorhiza sp., by sequencing the internal transcribed spacer (ITS) regions of the ribosomal RNA gene. Germination of C. nervosa seeds was higher when inoculated with Epulorhiza sp. Uninoculated seeds of C. nervosa ceased to develop soon after the initiation of germination, and the embryo failed to rupture the seed testa. The isolated fungal hyphae entered the germinating seeds either through the pores in-between the integuments, or through the rhizoids. After the fungal establishment (peloton formation) in embryonic cells, the embryo transformed into a protocorm and after 45 days, 66% of the germinated seeds were transformed into protocorms. Nevertheless, promeristem formation occurred only after fungal association. Sixty-three percent of the protocorms developed their first leaf by 90 days and 62% of these produced a second leaf by 120 days after fungal inoculation. All the seedlings in green leaf stage produced roots and contained fungal pelotons. Our results suggest that the Epulorhiza sp. could be successfully used in the in vitro production of C. nervosa for their reintroduction into its natural environment.     

Proteome changes in Oncidium sphacelatum (Orchidaceae) at different trophic stages of symbiotic germination

Mutualistic symbioses between plants and fungi are a widespread phenomenon in nature. Particularly in orchids, association with symbiotic fungi is required for seed germination and seedling development. During the initial stages of symbiotic germination, before the onset of photosynthesis, orchid protocorms are fully mycoheterotrophic. The molecular mechanisms involved in orchid symbiotic germination and development are largely unknown, but it is likely that changes in plant energy metabolism and defense-related responses play a central role in these processes. We have used 2D-LC-MS/MS coupled to isobaric tagging for relative and absolute quantification to identify proteins with differential accumulation in Oncidium sphacelatum at different stages of mycorrhizal protocorm development (achlorophyllous and green protocorms) after seed inoculation with a Ceratobasidium sp. isolate. We identified and quantified 88 proteins, including proteins putatively involved in energy metabolism, cell rescue and defense, molecular signaling, and secondary metabolism. Quantitative analysis showed that the expected changes in carbon metabolism in green protocorms were accompanied by enhanced accumulation of proteins involved in the modulation of reactive oxygen species homeostasis, defense-related responses, and phytoalexins and carotenoid biosynthesis. Our results suggest profound metabolic changes in orchid protocorms during the switch from the fully mycoheterotrophic to the photosynthetic stage. Part of these changes may be also related to the obligatory nature of the interaction with the endomycorrhizal fungus.     

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.