Transformed soybean (Glycine max) roots as a tool for the study of the arbuscular mycorrhizal symbiosis

Ri T-DNA transformed roots have been used effectively in studying the interaction between various plant hosts and arbuscular mycorrhizal (AM) fungi. We investigated the in vitro monoxenic symbiosis between the AM fungus Glomus intraradices and transformed soybean roots (TSRs). Comparisons were made between TSR system and plants of the same genotype. The extraradical fungal structures generated in vitro culture showed normal development. Straight runner hyphae branched into short simple branched absorbing structures and spores were initiated. AM symbiosis was confirmed by the presence of arbuscules and vesicles in cortical cells of the TSRs. The frequency of intraradical colonization in TSRs was higher than in plants grown in soil, whereas the intensity values of intraradical colonization in TSR cultures were similar to those in whole plants. These results show that TSR cultures were able to support the growth and characteristic development of G. intraradices.     

Mycelium development and architecture, and spore production of Scutellospora reticulata in monoxenic culture with Ri T-DNA transformed carrot roots

Mycelium development and architecture and spore production were studied in Scutellospora reticulata from single-spore isolates grown with Ri T-DNA transformed carrot root-organ culture in monoxenic system. Culture establishment, anastomosis occurrence and auxiliary cell development also were examined. Seventy percent of the pregerminated disinfected spores colonized the transformed carrot roots. After 8 mo, the average spore production was 56 (24-130) per 30 cm(3) of medium. Of the spores produced, 75% germinated and produced new generations in monoxenic culture. The mycelium network was formed by thick light-brown hyphae, which exhibit two major architecture patterns related to either root colonization or resource exploitation, and lower-order hyphae, bearing auxiliary cells, branched absorbing structures (BAS), hyphal swellings (HS) and forming anastomoses. BAS were formed abundantly in extramatrical mycelium and frequently had HS resembling vesicles, a feature not previously reported in the Gigasporaceae, to the best of our knowledge. Few anastomosis were observed within the mycelium and most often corresponded to a healing mechanism that form hypha bridges to reconnect broken hyphae or overcoming obstructed areas within a hypha. Numerous auxiliary cells were produced during culture development and their role was inferred.     

丛枝菌根真菌培养方法研究进展

文章结合最新研究成果着重从十个不同的层面对丛枝菌根真菌(AM真菌)的培养方法研究做了较为系统的介绍与评述。认为活体宿主植物盆栽培养法是最简单、最容易、也是最可靠的AM真菌培养方法,玻璃珠分室培养可方便地将培养基质与AM真菌分开,能获得纯净的AM真菌菌体,具有其它方法不可替代的作用,AM真菌单孢无菌的分室Ri T-DNA转型胡萝卜根双重离体培养是获得AM真菌纯净菌体和研究AM真菌遗传、生理、生化等特性的理想方法,以此方法为基础,在根室中补充碳源、在菌丝生长室置换培养基、多次收获菌体的转型根改良双重培养法是提高某些AM真菌孢子产量的力荐方法。     

Interactions between the arbuscular mycorrhizal (AM) fungus Glomus intraradices and nontransformed tomato roots of either wild-type or AM-defective phenotypes in monoxenic cultures

Monoxenic symbioses between the arbuscular mycorrhizal (AM) fungus Glomus intraradices and two nontransformed tomato root organ cultures (ROCs) were established. Wild-type tomato ROC from cultivar “RioGrande 76R” was employed as a control for mycorrhizal colonization and compared with its mutant line (rmc), which exhibits a highly reduced mycorrhizal colonization (rmc) phenotype. Structural features of the two root lines were similar when grown either in soil or under in vitro conditions, indicating that neither monoxenic culturing nor the rmc mutation affected root development or behavior. Colonization by G. intraradices in monoxenic culture of the wild-type line was low (<10%) but supported extensive development of extraradical mycelium, branched absorbing structures, and spores. The reduced colonization of rmc under monoxenic conditions (0.6%) was similar to that observed previously in soil. Extraradical development of runner hyphae was low and proportional to internal colonization. Few spores were produced. These results might suggest that carbon transfer may be modified in the rmc mutant. Our results support the usefulness of monoxenically obtained mycorrhizas for investigation of AM colonization and intraradical symbiotic functioning.     

Establishment of monoxenic culture between the arbuscular mycorrhizal fungus Glomus sinuosum and Ri T-DNA-transformed carrot roots

We report for the first time the establishment of an arbuscular mycorrhizal association between Glomus sinuosum (= Sclerocystis sinuosa) and transformed Ri T-DNA carrot (Daucus carota L.) roots in monoxenic culture. The G. sinuosum sporocarps survived not as single spores, but as sporocarps in the environment. The mode of germination of G. sinuosum was by extension of hyphae around the sporocarp. Numerous vegetative spores, arbuscules and vesicles were produced after the roots were infected by the hyphae. New mature sporocarps started to form after four months in the culture system. Forty-seven sporocarps were produced on average in each culture dish after six months, and these newly produced sporocarps were capable of germination in the growth medium.     

Cooccurring plants forming distinct arbuscular mycorrhizal morphologies harbor similar AM fungal species

Arbuscular mycorrhizal (AM) fungal spores were isolated from field transplants and rhizosphere soil of Hedera rhombea (Miq) Bean and Rubus parvifolius L., which form Paris-type and Arum-type AM, respectively. DNA from the spore isolates was used to generate molecular markers based on partial large subunit (LSU) ribosomal RNA (rDNA) sequences to determine AM fungi colonizing field-collected roots of the two plant species. Species that were isolated as spores and identified morphologically and molecularly were Gigaspora rosea and Scutellospora erythropa from H. rhombea, Acaulospora longula and Glomus etunicatum from R. parvifolius, and Glomus claroideum from both plants. The composition of the AM fungal communities with respect to plant trap cultures was highly divergent between plant species. Analysis of partial LSU rDNA sequences amplified from field-collected roots of the two plant species with PCR primers designed for the AM fungi indicated that both plants were colonized by G. claroideum, G. etunicatum, A. longula, and S. erythropa. G. rosea was not detected in the field-collected roots of either plant species. Four other AM fungal genotypes, which were not isolated as spores in trap cultures from the two plant species, were also found in the roots of both plant species; two were closely related to Glomus intraradices and Glomus clarum. One genotype, which was most closely related to Glomus microaggregatum, was confined to R. parvifolius, whereas an uncultured Glomeromycotan fungus occurred only in roots of H. rhombea. S. erythropa was the most dominant fungus found in the roots of H. rhombea. The detection of the same AM fungal species in field-collected roots of H. rhombea and R. parvifolius, which form Paris- and Arum-type AM, respectively, shows that AM morphology in these plants is strongly influenced by the host plant genotypes as appears to be the case in many plant species in natural ecosystems, although there are preferential associations between the hosts and colonizing AM fungi in this study.     

Infectivity of monoaxenic subcultures of the arbuscular mycorrhizal fungus Glomus versiforme associated with Ri-T-DNA-transformed carrot root

  Glomus versiforme was associated in vitro with Ri-T-DNA-transformed carrot root and after 4 months of cultivation, numerous axenic arbuscular mycorrhizal (AM) propagules were obtained. Three successive generations of spores and mycorrhizal root pieces were obtained by reassociating a 4-month-old root piece with a new carrot root. A biological test was conducted to assess the infectivity of the three generations of inoculum. Both for spores and mycorrhizal root pieces, a significant decrease in infectivity was observed among the successive generations. Mycorrhizal root pieces however, exhibited, higher infectivity than spores. These results show the possibility of maintaining AM fungi cultures in axenic conditions for a long time and raise questions about the loss of infectivity among the generations. The necessity of maintaining the same strains in vitro and in vivo in two separate collections is discussed. Received: 15 January 1996 / Received revision: 28 May 1996 / Accepted: 16 June 1996     

Aquaporin genes GintAQPF1 and GintAQPF2 from Glomus intraradices contribute to plant drought tolerance

Arbuscular mycorrhizal (AM) symbiosis, established between AM fungi (AMF) and roots of higher plants, occurs in most terrestrial ecosystems. It has been well demonstrated that AM symbiosis can improve plant performance under various environmental stresses, including drought stress. However, the molecular basis for the direct involvement of AMF in plant drought tolerance has not yet been established. Most recently, we cloned two functional aquaporin genes, GintAQPF1 and GintAQPF2, from AM fungus Glomus intraradices. By heterologous gene expression in yeast, aquaporin localization, activities and water permeability were examined. Gene expressions during symbiosis in expose to drought stress were also analyzed. Our data strongly supported potential water transport via AMF to host plants. As a complement, here we adopted the monoxenic culture system for AMF, in which carrot roots transformed by Ri-T DNA were cultured with Glomus intraradices in two-compartment Petri dishes, to verify the aquaporin gene functions in assisting AMF survival under polyethylene glycol (PEG) treatment. Our results showed that 25% PEG significantly upregulated the expression of two aquaporin genes, which was in line with the gene functions examined in yeast. We therefore concluded that the aquaporins function similarly in AMF as in yeast subjected to osmotic stress. The study provided further evidence to the direct involvement of AMF in improving plant water relations under drought stresses.     

Influence of Soybean Cultivar on Reproduction of Heterodera glycines in Monoxenic Culture

Nematodes produced in monoxenic culture are used for many research purposes. To maximize the number of Heterodera glycines produced in culture, 24 soybean cultivars (maturity groups 0-8) were evaluated for host suitability. A strain of H. glycines race 3, maintained in monoxenic culture on excised soybean root tips of cv. Kent, was inoculated into 20 petri dishes of each cultivar. The highest numbers of first-generation females per petri dish were produced on cultivars Bass, Williams 82, Kent, Proto, and Chapman, and the lowest on cultivars Lambert and Chesapeake. A diapause-like period with decreased nematode production was recorded on some cultivars but not others. Six generations of cultivation on CX 366 did not affect the number of females produced. The results indicated that soybean maturity group could not be used as a parameter for selecting the optimum cultivars for nematode production, and that only J2 petri dishes needed to be counted to determine a 60-female difference per petri dish among cultivars. This study demonstrated that H. glycines populations in monoxenic culture can be more than quadrupled by selection of an appropriate soybean cultivar.     

不同基质多代培养对蚧虫病原真菌蜡蚧霉致病力的影响

【目的】研究昆虫病原真菌蜡蚧霉Lecanicilliurn lecanii(Zimmermann.)菌株No.V3.4504在不同培养基上继代培养,对菌种的菌落生长特性、胞外酶活力和对蚧虫致病力的影响。【方法】试验菌种蜡蚧霉菌株No.V3.4504是从染病蚧虫上分离的。试验蚧虫是沙里院褐球蚧Rhodococcus sariuoni Borchsenius和日本龟蜡蚧Ceroplastes japonicus Green。采用7种培养基继代培养多代。观察菌落形态特征、测定生长速率、产孢量、胞外蛋白酶和几丁质酶活性及对蚧虫的致死率。【结果】在PDA培养基上,菌落生长速率最快,但产孢量最低,胞外蛋白酶和几丁质酶的活性均呈逐代下降趋势,对两种蚧虫致死率也最低;增加蛋白胨对改善菌种致病力没有明显效果;在增加蚧虫尸体的D、E、F培养基上,菌落生长速率虽然较慢,但产孢量上升为8.83×106-9.13×106孢子/cm2。蛋白酶和几丁质酶的活性平均达到2.16-2.13 U/g和1.01-1.03 U/g,对两种蚧虫的致死率分别在55%-58%和39%-42%;在活蚧虫上连续培养3代,蛋白酶和几丁质酶的活性最高,为3.08-2.92 U/g和1.45-1.42 U/g,是PDA培养基上的1.6倍。对两种蚧虫的致死率也最高,分别达到71.30%和58.89%。蛋白酶和几丁质酶的活性与蚧虫死亡率呈正直线相关关系。【结论】采用PDA培养基连续多代培养会引起菌株No.V3.4504明显退化;在培养基中加入蚧虫尸体,对于保持菌种活力有明显效果;在活蚧虫体上继代培养对复壮菌种,提高菌种毒力的效果最佳。     

Colonization potential of in vitro-produced arbuscular mycorrhizal fungus spores compared with a root-segment inoculum from open pot culture

 A reliable inoculum, free from other microorganisms, to produce arbuscular mycorhizal (AM) plants is of the greatest importance when studying the interaction between AM plants and soil microorganisms. We investigated the colonization of leeks from monoxenic in vitro-produced Glomus intraradices spores. The isolated spores were produced using a two-compartment in vitro growth system previously described. A spore suspension was used as inoculum and was compared to the inoculum potential of endomycorrhizal root segments of pot-grown leek (Allium porrum L.) plants. The leeks were grown in a controlled environment and two types of sterilized growth media were tested: calcined montmorillonite clay and a soil mix. Root colonization progressed faster in the soil mix than in the clay. However, in this medium, after an initial delay, root colonization from in vitro-produced spores was essentially the same as that observed with the root-segment inoculum, reaching 44% and 58% respectively, after 16 weeks. Leek roots colonized by the monoxenically-produced spores harbored only the studied AMF fungi while the roots colonized from the root segments were substantially contaminated by other fungi. Accepted: 25 December 1998     

Characterizing and handling different kinds of AM fungal spores in the rhizosphere

Spores are important propagules as well as the most reliable species-distinguishing traits of arbuscular mycorrhizal (AM) fungi. During surveys of AM fungal communities, spore enumeration and spore identification are frequently conducted, but generally little attention is given to the age and viability of the spores. In this study, AM fungal spores in the rhizosphere were characterized as live or dead by vital staining and by performing a germination assay. A considerable proportion of the spores in the rhizosphere were dead despite their intact appearance. Furthermore, morphological and molecular analyses of spores to determine species identity revealed that both viable spores and dead spores with contents were identified. The accurate identification of spores at different developmental stages on the basis of morphology requires considerable experience. Our findings suggest that surveys of AM fungal communities based on spore enumeration and morphological and molecular identification are likely to be inaccurate, primarily because of the large proportion of dead spores in the rhizosphere. A viability check is recommended prior to spore molecular identification, and the use of trap cultures would give more reliable morphological identification results. We show that the abundance and activity of AM fungi in the rhizosphere can be determined by calculating the density of viable spores and the density of spores that could germinate. The adoption of these methods should provide a more reliable basis for further AM fungal community analysis.     

Invasion of spores of the arbuscular mycorrhizal fungus Gigaspora decipiens by Burkholderia spp

Burkholderia species are bacterial soil inhabitants that are capable of interacting with a variety of eukaryotes, in some cases occupying intracellular habitats. Pathogenic and nonpathogenic Burkholderia spp., including B. vietnamiensis, B. cepacia, and B. pseudomallei, were grown on germinating spores of the arbuscular mycorrhizal fungus Gigaspora decipiens. Spore lysis assays revealed that all Burkholderia spp. tested were able to colonize the interior of G. decipiens spores. Amplification of specific DNA sequences and transmission electron microscopy confirmed the intracellular presence of B. vietnamiensis. Twelve percent of all spores were invaded by B. vietnamiensis, with an average of 1.5 x 10(6) CFU recovered from individual infected spores. Of those spores inoculated with B. pseudomallei, 7% were invaded, with an average of 5.5 x 10(5) CFU recovered from individual infected spores. Scanning electron and fluorescence microscopy provided insights into the morphology of surfaces of spores and hyphae of G. decipiens and the attachment of bacteria. Burkholderia spp. colonized both hyphae and spores, attaching to surfaces in either an end-on or side-on fashion. Adherence of Burkholderia spp. to eukaryotic surfaces also involved the formation of numerous fibrillar structures.     

Genetic variation of morphological characters within a single isolate of the endomycorrhizal fungus Glomus clarum (Glomaceae)

The nature of variation in morphological characters in spores of arbuscular endomycorrhizal fungi (Order Glomales, Class Zygomycetes) has received little attention, despite the importance of these characters in modern taxonomy of the order. We tested the hypothesis that genetic variation exists in spore size and color (presumably important taxonomic characters) within a single isolate of the glomalean fungus Glomus clarum. Phenotypic variation in size and color of spores was determined from a pot culture population (designated P). A 10% selection pressure was imposed on replicate pot cultures of the first progeny culture generation (G1) by selecting the smallest, largest, yellowest, and whitest spores from the P generation and inoculating Sorghum bicolor plants. The experiment was repeated for another generation (G2), but with a 5% selection pressure. In both the G1 and G2 generations, significant differences in spore size and color were observed among the various treatments, indicating substantial genetic variation in these characters. Despite efforts to keep the physical environment constant across generations, we observed variation in the overall means of spore size and color among the generations (regardless of treatment), indicating a strong nongenetic influence on character expression. This study provides empirical evidence that will help delimit species boundaries among isolates of Glomus clarum and similar morphospecies. It also demonstrates a promising method to help elucidate the nature of character diversity in obligately asexual fungi.     

Evidence for specificity of cultivable bacteria associated with arbuscular mycorrhizal fungal spores

Bacteria associated with arbuscular mycorrhizal (AM) fungal spores may play functional roles in interactions between AM fungi, plant hosts and defence against plant pathogens. To study AM fungal spore-associated bacteria (AMB) with regard to diversity, source effects (AM fungal species, plant host) and antagonistic properties, we isolated AMB from surface-decontaminated spores of Glomus intraradices and Glomus mosseae extracted from field rhizospheres of Festuca ovina and Leucanthemum vulgare. Analysis of 385 AMB was carried out by fatty acid methyl ester (FAME) profile analysis, and some also identified using 16S rRNA gene sequence analysis. The AMB were tested for capacity to inhibit growth in vitro of Rhizoctonia solani and production of fluorescent siderophores. Half of the AMB isolates could be identified to species (similarity index 0.6) within 16 genera and 36 species. AMB were most abundant in the genera Arthrobacter and Pseudomonas and in a cluster of unidentified isolates related to Stenotrophomonas. The AMB composition was affected by AM fungal species and to some extent by plant species. The occurrence of antagonistic isolates depended on AM fungal species, but not plant host, and originated from G. intraradices spores. AM fungal spores appear to host certain sets of AMB, of which some can contribute to resistance by AM fungi against plant pathogens.     

并基角毛藻若干分类学疑问的初步探讨

并基角毛藻是硅藻门角毛藻属的典型种类, 以“相邻角毛基部并行融合”作为标志性特征, 但该特征是否稳定, 及如何赋予其分类学价值?尚存较多争议。研究以符合现存并基角毛藻分类标准的藻株作为目标藻株, 采用毛细管显微操作技术从我国沿海代表水域分离藻株, 建立了目标藻株的单克隆培养株系, 利用光学显微镜、扫描电镜和透射电镜分别对其形态学特征进行观察, 同时还扩增了核糖体大亚基编码基因的D1-D3区序列, 并构建系统进化树。综合分析形态学特征和分子系统学数据, 初步得到以下结论: (1)具有相同遗传特征的并基角毛藻株系在“相邻角毛基部并行融合”特征上具有不稳定性, 即“相邻角毛基部并行融合”不能作为并基角毛藻种类的标志性特征; (2)并基角毛藻和洛氏角毛藻作为相似种类, 均显示出较高的物种多样性, 高于目前的认知, 预示着或许存在隐形种或拟隐形种; (3)推测并基角毛藻单胞变型只是并基角毛藻原种的一个生活史阶段, 是并基角毛藻的同种异名, 不宜继续保留其独立的分类学地位。     

Axenic culture and characterization of Giardia ardeae from the great blue heron (Ardea herodias)

Trophozoites of Giardia ardeae were obtained from the great blue heron (Ardea herodias) and established in axenic culture using the TYI-S-33 medium. The generation time in culture for G. ardeae was 22-25 hr, which was 3-fold longer than for Giardia duodenalis (WB strain). A morphological comparison of trophozoites in the original intestinal isolate to those grown in culture revealed that they were identical for the following characteristics: a pyriform-shaped body, a ventral adhesive disc with a deep notch in the posterior border, teardrop-shaped nuclei, pleomorphism in median body structure ranging from a round-oval appearance (Giardia muris type) to that of a clawhammer (G. duodenalis type), and a single caudal flagellum on the right side (as viewed dorsally) with the left one being rudimentary. Analysis of the chromosomal migration patterns was performed by orthogonal-field-alternation gel electrophoresis and demonstrated that the pattern for G. ardeae was distinctly different from that for G. duodenalis (Portland 1-CCW strain). Bacterial symbionts were seen attached to trophozoites in the original isolate but could not be detected in cultured trophozoites using scanning electron microscopy, fluorescence light microscopy using the Hoechst 33258 dye for DNA localization, or by standard microbiological techniques using nonselective media for growing aerobic or anaerobic bacteria. This study demonstrated that avian-derived Giardia could be grown in axenic culture; based on morphological criteria and chromosomal migration patterns, that G. ardeae should be considered a distinct species; and that rationale for determining Giardia spp., based on median body structure alone, should no longer be considered adequate for classification at the species level.     

球孢白僵菌混菌培养的遗传学分析

放线酮抗性及34℃耐受性不同的球孢白僵菌两营养亲和单孢株经混合培养,能够形成异核体。在分生孢子形成的单倍化过程中,异核体中的染色体或其片段发生连续丢失,至少经4代准性循环,遗传性状才会趋于相对稳定。遗传标记及RAPD分析表明,异核体中染色体的丢失并非随机的,重组株的遗传性状表现为倾向选择,即子代主要只表现为某一母株的遗传性状,另一亲本型性状被完全抑制或其遗传物质被丢失。混合比例不同、培养介质不同可影响准性生殖过程及倾向选择频率。混菌培养有利于优良性状的保持。     

分室培养装置在丛枝菌根真菌研究中的应用及其发展

重点围绕玻璃珠分室培养系统、H形分室培养系统、根排斥室培养系统、供体自养植物的双分室体外培养系统、丛枝菌根(AM)真菌与普通植物根器官的双重培养系统、AM真菌与Ri T-DNA转型根的双重单胞无菌培养系统、AM真菌与Ri T-DNA转型根双重培养的改良分室单胞培养系统等7个不同的分室培养装置, 对AM真菌的培养类型及其应用进行了系统的评述。其中, 采用玻璃珠分室培养装置易于将AM真菌与培养基质分开, 能获得大量纯净的AM真菌繁殖体, 用于研究AM真菌对矿质元素和微量元素的吸收, 具有不可替代的作用。H形分室培养系统和根排斥室(RECs)培养系统均能够获得连续的、可切断的共生菌根网络(CMNs), 可用于研究植物-植物、植物-昆虫之间化感作用产生的信息交流。供体自养植物的双分室培养系统有益于研究AM真菌对宿主植物在单作和混作条件下生长效应的影响。AM真菌与植物根器官的双重培养系统为研究AM真菌的侵染过程及生理、生化特性提供了极大的方便, 同时为纯培养研究提供了重要的理论依据。AM真菌与Ri T-DNA转型根的双重单胞无菌培养体系可以获得AM真菌纯净菌体, 是研究AM真菌遗传、生理、生化等特性的理想方法。以AM真菌与Ri T-DNA转型根的双重单胞无菌培养系统为基础, 可以在菌丝生长室置换培养基、在根室中补充适量碳源, 并多次收获AM真菌繁殖体。转型根改良双重培养系统是提高AM真菌孢子接种剂产量的有效方法。综上所述, AM真菌的分室培养系统已经取得显著进展, 为开展个体、种群、群落等不同层次的菌根生态学研究提供了依据。