根癌农杆菌介导的地衣型真菌Cladonia metacorallifera的转化

以潮霉素抗性和增强型绿色荧光蛋白(enhanced green fluorescent protein,EGFP)作为筛选标记,利用地衣型真菌Cladonia metacorallifera的菌丝,成功实现了根癌农杆菌介导的遗传转化,PCR检测证明转化子中存在潮霉素抗性基因,共聚焦显微镜检测到转化子菌丝能够产生绿色荧光,证明EGFP能够在trp C启动子控制下在地衣型真菌中表达。     

鸭梨PPO与GFP融合基因的烟草转化及亚细胞定位观察

将鸭梨PPO基因与绿色萤光蛋白GFP基因相融合共同进行遗传转化的方式,对鸭梨多酚氧化酶开展细胞定位研究。通过克隆该酶基因除终止密码子TAA外长度为1 779bp的CDS序列,与绿色荧光蛋白基因重组构建了荧光表达载体pBI121-PPO-GFP,借助农杆菌转化烟草,转基因烟草叶片细胞经激光扫描共聚焦显微镜观察,绿色荧光蛋白荧光与叶绿体自发荧光相重合。结果表明鸭梨多酚氧化酶为叶绿体蛋白质。     

灰葡萄孢菌过氧化物酶体及细胞核的荧光蛋白标记

【目的】对灰葡萄孢菌(Botrytis cinerea)的细胞核和过氧化物酶体进行荧光蛋白标记,为研究其生长发育和侵染过程中细胞结构和细胞器动态提供基础。【方法】以绿色荧光蛋白(GFP)和红色荧光蛋白(DsRED、mCherry)为报告基因,利用根癌农杆菌介导转化(Agrobacterium tumefaciens mediated transformation,AtMT)将3种荧光蛋白标记载体分别导入灰葡萄孢菌标准菌株B05.10;通过PCR检测及荧光观察筛选和验证转化子,并进行单孢纯化;利用共聚焦显微镜记录细胞器荧光定位情况。【结果】获得了过氧化物酶体或细胞核稳定表达红、绿色荧光的重组单孢菌株,PCR验证表明标记基因成功整合入转化子基因组。在标记细胞核的菌株中,菌丝和孢子中可见多个明亮、圆形的荧光点,与DAPI染色共定位。标记过氧化物酶体的菌株中,菌丝和孢子中可见小点状绿色或红色荧光,在脂类物质诱导下荧光点数量明显增加,符合过氧化物酶体分布及动态特征。细胞壁染色结果显示,细胞壁染色产生的蓝色荧光与红、绿荧光蛋白的荧光互不干扰,标记效果良好。【结论】获得了理想的过氧化物酶体或细胞核荧光标记的灰葡萄孢菌菌株,为研究其细胞器动态以及生长发育与致病分子机制提供了参考和材料。     

根癌农杆菌介导的灰葡萄孢菌遗传转化研究

以pCAMBIA1300-N载体为骨架, 成功构建了以绿色荧光蛋白(gfp)为报告基因, 潮霉素(hph)为抗性筛选标记的载体pKPG, 并利用根癌农杆菌介导转化系统, 成功获得了能表达绿色荧光蛋白的重组灰葡萄孢菌。通过PCR检测转化子的绿色荧光蛋白基因和潮霉素抗性表达框, 观察菌丝和分生孢子的荧光表型, 以及gfp基因的Southern杂交验证, 结果表明：被测转化子基因组中均成功整合了目的基因片段。     

根癌农杆菌介导的巨大口蘑遗传转化体系的构建

以巨大口蘑菌丝为受体材料,利用含有双元质粒plasmid4的根癌农杆菌EHA105介导,首次成功建立了巨大口蘑的遗传转化体系。通过潮霉素抗性筛选、PCR鉴定和绿色荧光蛋白的检测,表明潮霉素抗性基因（Hyg）已经整合到巨大口蘑基因组中,增强型绿色荧光蛋白基因（eGFP）在巨大口蘑菌丝中获得表达,并能够稳定遗传。本研究建立了农杆菌介导的巨大口蘑遗传转化体系,为今后巨大口蘑的基因功能研究奠定了基础。     

拟南芥谷氨酸受体基因的亚细胞定位

为明确拟南芥谷氨酸受体1.3基因(AtGLR1.3)的亚细胞定位,该实验以拟南芥(Arabidopsis thalianaCo-lumbia ecotype)为材料,运用PCR方法从其基因组中扩增得到了AtGLR1.3的启动子和基因序列,将其连接到载体pBIsGFP上,构建成AtGLR1.3基因与绿色荧光蛋白基因融合的植物表达载体,通过农杆菌介导的花序浸润法将重组载体转化拟南芥野生型,转基因植株通过激光共聚焦扫描显微镜观察显示,GFP荧光信号存在于细胞质膜上,表明AtGLR1.3为细胞膜蛋白.该结果为进一步研究AtGLR1.3的作用机理奠定了基础.     

AtRGS1-GFP融合蛋白对AtRGS1细胞定位的研究

应用Gateway克隆技术构建了以CaMV35S为启动子,含AtRGS1-GFP融合基因的植物表达载体,并分别用根癌农杆菌介导法和PEG介导法转化拟南芥野生型（C01）悬浮细胞系和幼苗叶片原生质体,利用荧光显微镜观察AtRGS1-GFP融合基因在转化受体系统中的表达与定位。结果显示,在含AtRGS1-GFP融合基因的转化细胞系中,GFP绿色荧光在细胞膜（壁）上特异表达;原生质体瞬时表达系统中,GFP绿色荧光在细胞膜上强烈表达,表明AtRGS1蛋白定位于细胞质膜上。     

农杆菌介导的斑玉蕈遗传转化

【目的】将农杆菌介导的转化应用于重要的工厂化栽培食用菌斑玉蕈中,建立稳定的农杆菌介导的斑玉蕈遗传转化技术。【方法】将构建的双元载体pYN6982转入农杆菌LBA4404菌株中,以斑玉蕈SIEF3133菌株打碎的双核菌丝为受体材料,利用根癌农杆菌介导的转化方法进行斑玉蕈转化试验。【结果】经潮霉素抗性筛选、PCR鉴定以及有丝分裂稳定性试验验证,表明潮霉素磷酸转移酶基因(hph)已经整合到斑玉蕈的基因组中;转基因斑玉蕈菌丝在荧光显微镜下可以观测到绿色荧光,表明增强型绿色荧光蛋白基因(egfp)已经在转基因斑玉蕈菌株中获得了表达;通过PCR检测,随机挑选的8个转基因斑玉蕈菌株中有2个可以扩增出载体转移DNA(T-DNA)边界重复序列外的卡那霉素基因(kan)序列。【结论】获得了稳定遗传和表达的斑玉蕈转基因菌株,建立了农杆菌介导的斑玉蕈遗传转化方法。农杆菌介导的斑玉蕈遗传转化中,存在载体T-DNA边界重复序列之外的DNA序列转移到转基因斑玉蕈中的现象,有待进一步研究。     

两种瞬时表达体系研究拟南芥Profilin-1的亚细胞定位

使用两种瞬时表达方法研究Profilin-1(PRF1)的亚细胞定位,并比较了2种瞬时表达体系在亚细胞定位研究中的优缺点。利用拟南芥幼叶作为材料,提取叶片的RNA,采用特异性引物RT-PCR的方法克隆PRF1基因,连接到p CAMBIA1300-GFP的改造载体上,成功的构建p CAMBIA1300-GFP-PRF1的表达载体。然后分别利用PEG转化拟南芥原生质体、农杆菌浸染烟草叶片两种技术进行了瞬时表达,并在激光共聚焦显微镜下观察绿色荧光蛋白(GFP)融合蛋白的表达。研究结果表明,将PRF1基因导入拟南芥的原生质体和烟草表皮细胞后,融合蛋白绿色荧光均能被观察到,PRF1基因与GFP融合蛋白的产物在烟草表皮细胞中主要定位在细胞质和外周细胞器中,在拟南芥的原生质体中的细胞核和细胞质中都有定位。两种不同的瞬时表达体系中PRF1蛋白的定位出现了不同,这可能与同源或异源表达的植物的特性相关。     

HRB2慢病毒表达质粒的构建核蛋白细胞内定位的研究

目的:构建重组HIV-1相关结合蛋白2(HIV-1 rev binding protein 2)基因的真核融合表达质粒plenti-OFP-HRB2,用慢病毒表达系统感染HEKTER细胞.对过表达GFP-HRB2基因的细胞在激光共聚焦显微镜下观察,研究HRB2蛋白在细胞中的分布规律.方法:Trizol法提取人睾丸组织总RNA进行RT-PCR,将纯化的扩增产物HRB2与克隆载体plp-GFP-Cl连接、转化感受态细菌E.coli XLblue.测序正确后将质粒plp-GFP-HRB2与真核表达质粒plenti-Cl分别进行双酶切,连接后转化.将构建正确的plenti-GFP-HRB2重组质粒、△8.91、pvsvg瞬时共转染293T细胞后,用荧光显微镜观察绿色荧光蛋白的表达.收集包装病毒后感染HEKTER细胞.细胞生长一周后,将细胞铺玻片上用激光共聚焦显微镜观察.结果:构建的plenti-GFP-HRB2真核表达质粒经PCR鉴定及测序均说明人源HRB2基因已与plenti-GFP载体正确重组.瞬时转染293T细胞后能观察到绿色荧光.稳定感染后的HEKTER细胞经激光共聚焦显微镜观察后发现,HRB2蛋白在核仁处富集,在细胞核的其它部位少量分布,在胞浆中几乎没有分布.结论:人源HRB2基因表达的相关蛋白具有一个KH结构域,属于KH结构域家族的成员.稳定表达GFP-HRB2融合蛋白的细胞系的成功构建,为深入研究HRB2的入核机制、HRB2蛋白的在细胞分裂、RNA剪切等生物活动中的作用奠定了重要的实验基础.     

Agrobacterium-mediated transformation of the ectomycorrhizal symbiont Laccaria bicolor S238N

The development of an efficient transformation system is required to alter the expression of symbiosis-regulated genes and to develop insertional mutagenesis in the ectomycorrhizal basidiomycete Laccaria bicolor S238N. Vegetative mycelium of this fungus was transformed by Agrobacterium tumefaciens-mediated gene transfer. The selection marker was the hygromycin resistance gene of Escherichia coli (hph) under the control of the gpd promoter from Agaricus bisporus and the CaMV 35S terminator as part of the T-DNA. PCR amplification of hph and Southern blot analyses showed that the genome of the hygromycin-resistant transformants contained the cassette. The latter proved mostly single copy and random integration of part of the transgene into the fungal genome. A. tumefaciens-mediated gene transfer should facilitate future development of insertional mutagenesis, targeted gene disruption and RNA interference technology in L. bicolor.     

Coinoculation of aseptically grown Douglas fir with pairs of ectomycorrhizal fungi

Douglas fir seedlings grown under aseptic conditions in a peat-vermiculite substrate were inoculated with four pairs of ectomycorrhizal fungi to assess the relative inoculum dosages needed to establish two mycorrhizal fungi simultaneously in the same root system. The dual fungal combinations tested were: Pisolithus arhizus + Rhizopogon subareolatus, P. arhizus + R. roseolus, Laccaria bicolor + P. arhizus and L. bicolor + R. subareolatus. A total of 12 ml of inocula per plant was applied at the rates: 0+12, 3+9, 6+6, 9+3, 12+0, and 0+0 (v+v) for each combination. After 3 months growth, the number of mycorrhizas and uninfected short roots as well as the total plant biomass produced were recorded. Inoculations were successful with the fungal combinations P. arhizus + R. subareolatus and L. bicolor + P. arhizus. Plants developed P. arhizus and R. subareolatus mycorrhizas only at the rate 9Pa + 3Rs; at other rates tested, only monospecific mycorrhizas were formed. Plants developed L. bicolor and P. arhizus mycorrhizas at the three rates containing both fungi. L. bicolor behaved as an aggressive root colonizer and its level of root colonization remained constant at increasing rates of P. arhizus inoculum. L. bicolor displaced R. subareolatus at all inocula rates. P. arhizus displaced R. roseolus except at the rate 3Pa + 9Rr, with only a low number of mycorrhizas formed by either fungus. Total plant biomass was significantly increased by the presence of any fungal combination up to four times the values for uninoculated controls. P. arhizus and R. subareolatus were more effective in promoting plant growth and stimulating short root formation than either L. bicolor or R. roseolus.     

Effects of red pine (Pinus resinosa Ait.) mycorrhizoplane-associated actinomycetes onin vitro growth of ectomycorrhizal fungi

Mycorrhizoplane-associated actinomycetes were isolated using an enrichment technique from red pine (Pinus resinosa Ait.) roots of seedlings recently outplanted onto cleared northern hardwood sites in the Upper Peninsula of Michigan, USA. Interactions were assessedin vitro between actinomycete isolates and three commonly occurring ectomycorrhizal fungi (Laccaria bicolor (Maire) Orton,L. laccata (Scop.: Fr.) Berk. and Br., andThelephora terrestris Fr.). Most actinomycete isolates exerted a range of effects on the growth of the three fungus isolates during the four week test period, inhibiting some while stimulating others; several inhibited growth of all three fungus isolates. Mycorrhizoplane-associated actinomycetes show potential for use as coinoculants with selected ectomycorrhizal fungi to optimize the soil microflora for developing seedlings.     

Arbuscular mycorrhizas and ectomycorrhizas of <Emphasis Type="Italic">Uapaca bojeri</Emphasis> L. (Euphorbiaceae): sporophore diversity,patterns of root colonization,and effects on seedling growth and soil microbial catabolic diversity

The main objectives of this study were (1) to describe the diversity of mycorrhizal fungal communities associated with Uapaca bojeri, an endemic Euphorbiaceae of Madagascar, and (2) to determine the potential benefits of inoculation with mycorrhizal fungi [ectomycorrhizal and/or arbuscular mycorrhizal (AM) fungi] on the growth of this tree species and on the functional diversity of soil microflora. Ninety-four sporophores were collected from three survey sites. They were identified as belonging to the ectomycorrhizal genera Afroboletus, Amanita, Boletus, Cantharellus, Lactarius, Leccinum, Rubinoboletus, Scleroderma, Tricholoma, and Xerocomus. Russula was the most frequent ectomycorrhizal genus recorded under U. bojeri. AM structures (vesicles and hyphae) were detected from the roots in all surveyed sites. In addition, this study showed that this tree species is highly dependent on both types of mycorrhiza, and controlled ectomycorrhization of this Uapaca species strongly influences soil microbial catabolic diversity. These results showed that the complex symbiotic status of U. bojeri could be managed to optimize its development in degraded areas. The use of selected mycorrhizal fungi such the Scleroderma Sc1 isolate in nursery conditions could be of great interest as (1) this fungal strain is very competitive against native symbiotic microflora, and (2) the fungal inoculation improves the catabolic potentialities of the soil microflora.     

Degradation of 14C-labelled lignin and dehydropolymer of coniferyl alcohol by ericoid and ectomycorrhizal fungi

The ability of ericoid and ectomycorrhizal fungi to utilize ¹⁴C-labelled lignin and O¹⁴CH₃-labelled dehydropolymer of coniferyl alcohol as sole C sources has been assessed in pure culture studies. The results indicate that ericoid mycorrhizal fungi are more effective in degrading lignin than ectomycorrhizal fungi. Amongst the ectomycorrhizal fungi the facultative mycorrhizal fungus Paxillus involutus degraded lignin more readily than those which are normally considered to be obligately mycorrhizal fungi such as Suillus bovinus and Rhizopogon roseolus. The importance of these lignin degrading capabilities is discussed in relation to the predominance of specific mycorrhiza forms along a gradient of increasing organic matter and hence lignin content of soil.     

An ectomycorrhizal fungus alters sensitivity to jasmonate,salicylate, gibberellin,and ethylene in host roots

The phytohormones jasmonate, gibberellin, salicylate, and ethylene regulate an interconnected reprogramming network integrating root development with plant responses against microbes. The establishment of mutualistic ectomycorrhizal symbiosis requires the suppression of plant defense responses against fungi as well as the modification of root architecture and cortical cell wall properties. Here, we investigated the contribution of phytohormones and their crosstalk to the ontogenesis of ectomycorrhizae (ECM) between grey poplar (Populus tremula x alba) roots and the fungus Laccaria bicolor. To obtain the hormonal blueprint of developing ECM, we quantified the concentrations of jasmonates, gibberellins, and salicylate via liquid chromatography–tandem mass spectrometry. Subsequently, we assessed root architecture, mycorrhizal morphology, and gene expression levels (RNA sequencing) in phytohormone-treated poplar lateral roots in the presence or absence of L. bicolor. Salicylic acid accumulated in mid-stage ECM. Exogenous phytohormone treatment affected the fungal colonization rate and/or frequency of Hartig net formation. Colonized lateral roots displayed diminished responsiveness to jasmonate but regulated some genes, implicated in defense and cell wall remodelling, that were specifically differentially expressed after jasmonate treatment. Responses to salicylate, gibberellin, and ethylene were enhanced in ECM. The dynamics of phytohormone accumulation and response suggest that jasmonate, gibberellin, salicylate, and ethylene signalling play multifaceted roles in poplar L. bicolor ectomycorrhizal development.     

Structure and histochemistry of mycorrhizae synthesized between Arbutus menziesii (Ericaceae) and two basidiomycetes,Pisolithus tinctorius (Pisolithaceae) and Piloderma bicolor (Corticiaceae)

Arbutoid mycorrhizae were synthesized in growth pouches between Arbutus menziesii Pursch. (Pacific madrone) and two broad host range basidiomycete fungi, Pisolithus tinctorius (Pers.) Coker and Couch and Piloderma bicolor (Peck) Jülich. P. tinctorius induced the formation of dense, pinnate mycorrhizal root clusters enveloped by a thick fungal mantle. P. bicolor mycorrhizae were usually unbranched, and had a thin or non-existent mantle. Both associations had the well-developed para-epidermal Hartig nets and intracellular penetration of host epidermal cells by hyphae typical of arbutoid interactions. A. menziesii roots developed a suberized exodermis which acted as a barrier to cortical cell penetration by the fungi. Ultrastructurally, the suberin appeared non-lamellar, but this may have been due to the imbedding resin. Histochemical analyses indicated that phenolic substances present in epidermal cells may be an important factor in mycorrhiza establishment. Analyses with X-ray energy dispersive spectroscopy showed that some of the granular inclusions present in fungal hyphae of the mantle and Hartig net were polyphosphate. Other inclusions were either protein or polysaccharides.     

Diversity and Spatial Structure of Belowground Plant–Fungal Symbiosis in a Mixed Subtropical Forest of Ectomycorrhizal and Arbuscular Mycorrhizal Plants

Plant–mycorrhizal fungal interactions are ubiquitous in forest ecosystems. While ectomycorrhizal plants and their fungi generally dominate temperate forests, arbuscular mycorrhizal symbiosis is common in the tropics. In subtropical regions, however, ectomycorrhizal and arbuscular mycorrhizal plants co-occur at comparable abundances in single forests, presumably generating complex community structures of root-associated fungi. To reveal root-associated fungal community structure in a mixed forest of ectomycorrhizal and arbuscular mycorrhizal plants, we conducted a massively-parallel pyrosequencing analysis, targeting fungi in the roots of 36 plant species that co-occur in a subtropical forest. In total, 580 fungal operational taxonomic units were detected, of which 132 and 58 were probably ectomycorrhizal and arbuscular mycorrhizal, respectively. As expected, the composition of fungal symbionts differed between fagaceous (ectomycorrhizal) and non-fagaceous (possibly arbuscular mycorrhizal) plants. However, non-fagaceous plants were associated with not only arbuscular mycorrhizal fungi but also several clades of ectomycorrhizal (e.g., Russula) and root-endophytic ascomycete fungi. Many of the ectomycorrhizal and root-endophytic fungi were detected from both fagaceous and non-fagaceous plants in the community. Interestingly, ectomycorrhizal and arbuscular mycorrhizal fungi were concurrently detected from tiny root fragments of non-fagaceous plants. The plant–fungal associations in the forest were spatially structured, and non-fagaceous plant roots hosted ectomycorrhizal fungi more often in the proximity of ectomycorrhizal plant roots. Overall, this study suggests that belowground plant–fungal symbiosis in subtropical forests is complex in that it includes “non-typical” plant–fungal combinations (e.g., ectomycorrhizal fungi on possibly arbuscular mycorrhizal plants) that do not fall within the conventional classification of mycorrhizal symbioses, and in that associations with multiple functional (or phylogenetic) groups of fungi are ubiquitous among plants. Moreover, ectomycorrhizal fungal symbionts of fagaceous plants may “invade” the roots of neighboring non-fagaceous plants, potentially influencing the interactions between non-fagaceous plants and their arbuscular-mycorrhizal fungal symbionts at a fine spatial scale.     

The mycorrhizal status and colonization of 26 tree species growing in urban and rural environments

Urban environments are highly disturbed and fragmented ecosystems that commonly have lower mycorrhizal fungal species richness and diversity compared to rural or natural ecosystems. In this study, we assessed whether the mycorrhizal status and colonization of trees are influenced by the overall environment (rural vs. urban) they are growing in. Soil cores were collected from the rhizosphere of trees growing in urban and rural environments around southern Ontario. Roots were extracted from the soil cores to determine whether the trees were colonized by arbuscular mycorrhizal fungi, ectomycorrhizal fungi, or both, and to quantify the percent colonization of each type of mycorrhizal fungi. All 26 tree species were colonized by arbuscular mycorrhizal fungi, and seven tree species were dually colonized by arbuscular mycorrhizal and ectomycorrhizal fungi. Overall, arbuscular mycorrhizal and ectomycorrhizal fungal colonization was significantly (p < 0.001) lower in trees growing in urban compared to rural environments. It is not clear what ‘urban’ factors are responsible for the reduction in mycorrhizal fungal colonization; more research is needed to determine whether inoculating urban trees with mycorrhizal fungi would increase colonization levels and growth of the trees.     

Dispersal of Spores of Mycorrhizal Fungi in Scats of Native Mammals in Tropical Forests of Northeastern Australia

One hundred and thirty-eight scat (faecal) samples from 17 mammal species native to forests of northeastern Queensland were examined for the presence of spores of both ectomycorrhizal and arbuscular mycorrhizal fungi. Spores of mycorrhizal fungi were found in 57 percent of scat samples representing 12 animal species (Aepyprymnus rufescens, Antechinus godmani, Bettongia tropica, Hypsiprymnodon moschatus, Isoodon macrourus, Melomys ceruinipes, Perameles nasuta, Rattus fuscipes, R. tunneyi, Thylogale stigmatica, Trichourur uulperula, Uromys caudimaculatus). Spores were absent in scats of Antechinus stuartii, Dasyurus hallucatus, Dendrolagus lumholtzi, Petaurus australis and Mesembriomys gouldii. Spores of ectomycorrhizal fungi occurred in 38 percent of scats, and all but one of these samples were from Eucalyptus-dominated sclerophyll forests. Based on the frequency and abundance of spores in scats, five mammals were considered active consumers of hypogeous mycorrhizal sporocarps in sclerophyll forests (A. rufescens, B. tropica, I. macrourus, P. nasuta, and U. caudimaculatus). Individual scats of these animals generally contained a range of distinctive spore types. Spores of arbuscular mycorrhizal fungi were found in low abundance in almost 40 percent of scat samples collected, from both sclerophyll forest and rainforest habitats. We suggest that the majoriry of these spores were acquired incidentally through ingestion of soil during foraging activities on the forest floor. Glasshouse inoculation experiments in which seedlings of Eucalyptus grandis and Sorghum bicolor were inoculated with scat material from several species of mammal demonstrated that the spores of ectomycorrhizal and arbuscular mycorrhizal fungi retained some viability and colonized the roots of host-plant seedlings. Insufficient information is known of the ecology of mycorrhizal fungi in Australia's tropical forests to speculate as to the implications of these findings for forest conservation and rehabilitation.