干旱胁迫下内生真菌感染对黑麦草光合色素和光合产物的影响

以含有内生真菌的黑麦草 (L olium perenne L.)种子为材料 ,采用加热处理方式构建内生真菌非感染的黑麦草种群 ,通过比较内生真菌感染 (EI)和非感染 (EF)植株在正常条件下和干旱胁迫条件下叶片相对水分含量、叶绿素、可溶性糖和淀粉含量等指标的差异 ,探讨黑麦草 EI和 EF种群对干旱胁迫的适应性差异。结果表明 :在中度胁迫后期 ,EI植株叶片的 RWC显著高于 EF植株 ,即 EI植株的保水能力更强。轻度水分胁迫下 ,内生真菌感染可使其宿主植物的可溶性糖含量增加 ,以增强宿主的渗透调节能力 ,随着干旱胁迫强度的加大 ,内生真菌的这一增益效应不再起作用 ,此时 ,宿主植物将更多的光合产物——淀粉积累于体内 ,以度过不良环境。第 2年春天 EI和 EF种群的恢复生长情况进一步表明 ,经过中度干旱胁迫后 ,EI种群的恢复更为迅速。生物量的大小是植物种群净光合作用能力的直接体现 ,研究中在中度干旱胁迫条件下 ,黑麦草 EI种群的生物量显著高于EF种群 ,但从光合色素的变化来看 ,相同水分状况下 EI和 EF植株的 Chla、Chlb以及 Car的变化趋势比较接近 ,这说明内生真菌感染并未缓解干旱胁迫对光合色素的破坏 ,内生真菌可能通过其它途径来改善宿主植物的光合能力     

内生真菌感染对黑麦草抗盐性的影响

以感染内生真菌的多年生黑麦草（Lolium perenne L．）（SR4000）为实验材料,建植内生真菌感染（EI）和不感染（EF）的黑麦草种群,并对其进行盐胁迫实验,通过观察生长和生理生态指标的变化,分析内生真菌对宿主植物抗盐性的影响。结果表明,内生真菌感染对宿主黑麦草的营养生长没有增益效应,相反在高盐浓度下,EI种群的分蘖能力和地上部分生物量均低于EF种群;但内生真菌能够改变宿主种群生物量的分配格局,将更大比例的生物量分配于根系。在高盐浓度下,内生真菌感染可导致黑麦草叶内的脯氨酸含量显著增加、可溶性糖含量显著降低,但对PSⅡ光化学效率Fv/Fm值的变化没有影响。总体来看,内生真菌感染并未改善宿主黑麦草的抗盐性。     

渗透胁迫下内生真菌感染对黑麦草幼苗生长的影响

以含有内生真菌的黑麦草(Lolium perenne L．)种子为材料,采用4C冰箱内和20℃光照培养箱内保存18个月的方式分别构建内生真菌感染(EI)和内生真菌非感染(EF)的黑麦草种群,通过比较EI和EF种群在正常条件下(对照)和渗透胁迫条件下种子发芽、幼苗生长等方面的差异,探讨内生真菌对其宿主植物的直接和间接影响。结果表明：在对照和胁迫条件下,E1种子的发芽势均明显高于EF种子,而只在重度渗透胁迫下,E1种子的发芽率才显著高于EF种子。对于黑麦草幼苗而言,渗透胁迫下内生真菌对宿主植物的地上部分和地下部分均有增益作用,最终表现为E1种群的总生物量显著高于EF种群,其中对地上部分的促进作用表现为内生真菌的存在不仅提高了宿主叶片的延伸速率、使EI叶片比EF叶片更长、叶面积更大,而且在重度胁迫下,E1种群的分蘖数也显著高于EF种群;对地下部分的促进作用表现为EI种群的根系总长度和根干重均高于EF种群。     

内生真菌感染对干旱胁迫下黑麦草生长的影响

 内生真菌是生活在健康植物的茎叶内,形成不明显感染的一类真菌。以黑麦草（Lolium perenne L.）为实验材料,研究在不同强度的干旱胁迫下内生真菌（Neotyphodium lolii）侵染对其叶片延伸生长、分蘖数和生物量的影响。结果表明,与非感染种群相比,内生真菌感染对黑麦草叶片延伸速率无明显促进作用;内生真菌感染种群具有明显较多的分蘖数;在重度胁迫并经过恢复期后,内生真菌感染种群具有较高的根冠比。因而内生真菌可能通过提高植物的分蘖能力和促进有机物向根系的分配来促进宿主植物的营养生长并提高其抗旱性     

黑麦草-内生真菌共生体对磷缺乏的生理生态反应

选取感染和未感染的黑麦草为材料,在田间盆栽条件下研究内生真菌感染对宿主植物抵抗磷胁迫方面的贡献。结果表明,土壤中缺磷或内生真菌感染对黑麦草地上部生长的影响不显著,但内生真菌感染对植株地下部生长和生理指标有明显影响。缺磷条件下,内生真菌感染有助于黑麦草地下部分的生长,表现在根系总长度更长,生物量更大;同时根中酚类物质和有机酸的含量也显著高于未感染植株,但因酚类物质和有机酸总量增加的同时并未伴随着二者浓度的增加,由此推测,内生真菌在改变宿主黑麦草根系代谢活动方面的贡献有限。此外,内生真菌感染显著提高了宿主植物的磷利用效率,这可能和缺磷条件下内生真菌感染植株具有更高的酸性磷酸酶活性有关。     

土壤干旱对黄土高原乡土树种水分代谢与渗透调节物质的影响

以黄土高原4个乡土树种的幼苗为试验材料,采用盆栽方式模拟土壤干旱环境,研究土壤干旱对不同树种水分代谢与渗透调节物质的影响。结果表明,大叶细裂槭、虎榛子叶水势、叶片含水量下降迅速,叶片离体保水能力降幅明显;白刺花、辽东栎则表现为叶水势、叶片含水量缓慢下降,组织相对含水量在中度胁迫下略有上升。白刺花在不同水分处理条件下离体叶片保水力明显高于其它树种。1个树种可溶性糖含量随土壤干旱程度加剧明显增加,可溶性蛋白质含量在树种之间变化较为复杂,无明显规律性。K^ 离子含量和游离脯氨酸含量在中度水分胁迫下均有不同程度升高。白刺花在土壤干旱进程中,可溶性蛋白质含量、K^ 离子含量和游离脯氨酸含量均明显高于其它树种。综合水分代谢和渗透调节物质来看,水分胁迫条件下,白刺花以保持高水势、减少组织水分散失和增加渗透调节物质来提高细胞原生质浓度,增强其抗旱性。     

内生真菌侵染对黑麦草种子萌发、幼苗生长及渗透胁迫抗性的影响

 以含有内生真菌的黑麦草(Lolium perenne L.)种子为材料,采用4 ℃冰箱内和20 ℃培养箱内保存18个月的方式分别构建内生真菌侵染（EI）和内生真菌非侵染（EF）的黑麦草种群,通过比较EI和EF种群在正常条件下（对照）和渗透胁迫条件下种子发芽、幼苗生长等方面的差异,探讨内生真菌对其宿主植物的直接和间接影响。结果表明：在对照和胁迫条件下,EI种子的发芽势及发芽率均明显高于EF种子,而在重度胁迫下EI植株的叶延伸速率、根系总长度高于EF植株。内生真菌对宿主植物分蘖数和生物量的变化没有促进作用,但     

内生真菌侵染对黑麦草种子萌发、幼苗生长及渗透胁迫抗性的影响

以含有内生真菌的黑麦草(Lolium perenne L.)种子为材料,采用4 ℃冰箱内和20 ℃培养箱内保存18个月的方式分别构建内生真菌侵染（EI）和内生真菌非侵染（EF）的黑麦草种群,通过比较EI和EF种群在正常条件下（对照）和渗透胁迫条件下种子发芽、幼苗生长等方面的差异,探讨内生真菌对其宿主植物的直接和间接影响。结果表明：在对照和胁迫条件下,EI种子的发芽势及发芽率均明显高于EF种子,而在重度胁迫下EI植株的叶延伸速率、根系总长度高于EF植株。内生真菌对宿主植物分蘖数和生物量的变化没有促进作用,但     

渗透胁迫下多花黑麦草叶内过氧化物酶活性和脯氨酸含量以及质膜相对透性的变化

多花黑麦草幼苗于３ 叶期转移至１／２Ｈｏａｇｌａｎｄ 溶液中培养,同时加入ＰＥＧ６０００ 用以模拟５种强度的渗透胁迫。植物叶内过氧化物酶活性、游离脯氨酸含量和质膜相对透性均对渗透胁迫强度的增加作出了反应,但反应的敏感性依次降低。从时间进程上看,过氧化物酶活性升降在前,游离脯氨酸积累继之,嗣后出现质膜相对透性增高。每个测定日内叶片中游离脯氨酸含量与质膜相对透性呈显著至极显著正相关。     

干旱胁迫对甘草幼苗生长和渗透调节物质含量的影响

采用人工控制水分模拟干旱的处理方法,研究了干旱胁迫对甘草幼苗生长状况、水分状况和主要渗透调节物质含量的影响.结果显示:轻度干旱胁迫有利于甘草幼苗根系生长,植株根冠比加大.干旱胁迫下甘草根叶组织中相对含水量下降,束缚水/自由水升高.甘草幼苗组织中渗透调节物质可溶性蛋白、游离脯氨酸、可溶性糖含量在干旱胁迫下也均显著增加;且...     

植物内生菌及其防治植物病害的研究进展

综述了植物内生菌及其防治植物病害的研究进展.植物内生菌分布广,种类多,几乎存在于所有目前已研究过的陆生及水生植物中,目前全世界至少已在80个属290多种禾本科植物中发现有内生真菌,在各种农作物及经济作物中发现的内生细菌已超过120种.感染内生菌的植物宿主往往具有生长快速、抗逆境、抗病害、抗动物危害等优势,比未感染内生菌的植株更具生存竞争力.植物内生菌的防病机理主要表现在通过产生抗生素类,水解酶类,植物生长调节剂和生物碱类物质,与病原菌竞争营养物质,增强宿主植物的抵抗力以及诱导植物产生系统抗性等途径抑制病原菌生长.另外,对植物内生真菌和内生细菌的分离、筛选和检测方法;利用植物内生菌控制植物病害的途径如人工接种内生菌,利用内生菌代谢产生的抗生素以及将内生菌作为基因工程的载体菌等进行了综述.同时,对植物内生菌作为生物防治因子未来发展前景及存在的问题进行了讨论.利用植物内生菌作为生物防治因子进行大田防病,需要考虑它的病理学、生态学和形态学等方面的影响.     

The interactive effects of plant microbial symbionts: a review and meta-analysis

In nature, plants often associate with multiple symbionts concurrently, yet the effects of tripartite symbioses are not well understood. We expected synergistic growth responses from plants associating with functionally distinct symbionts. In contrast, symbionts providing similar benefits to a host may reduce host plant growth. We reviewed studies investigating the effect of multiple interactions on host plant performance. Additionally, we conducted a meta-analysis on the studies that performed controlled manipulations of the presence of two microbial symbionts. Using response ratios, we investigated the effects on plants of pairs of symbionts (mycorrhizal fungi, fungal endophytes, and nitrogen-fixers). The results did not support the view that arbuscular mycorrhizal (AM) fungi and rhizobia should interact synergistically. In contrast, we found the joint effects of fungal endophytes and arbuscular mycorrhizal fungi to be greater than expected given their independent effects. This increase in plant performance only held for antagonistic endophytes, whose negative effects were alleviated when in association with AM fungi, while the impact of beneficial endophytes was not altered by infection with AM fungi. Generalizations from the meta-analysis were limited by the substantial variation within types of interactions and the data available, highlighting the need for more research on a range of plant systems.     

禾草内生真菌对其它微生物的影响研究进展

禾草内生真菌在宿主植物的茎叶等地上组织中普遍存在,不仅能够提高禾草对生物与非生物逆境的抗性,而且能够对周围环境中的不同微生物类群产生影响。主要总结了禾草Neotyphodium/Epichlo内生真菌对病原真菌、丛枝菌根真菌和土壤微生物的影响及其作用机理。发现禾草内生真菌普遍存在对病原真菌的抑制作用,而对丛枝菌根真菌存在不对称的竞争作用,且因种类而异。禾草内生真菌对土壤微生物群落的作用则会随着土壤类型和时间等外界因素发生变化。禾草内生真菌对不同类群微生物的影响机制主要包括:通过生态位竞争、抑菌物质分泌、诱导抗病性等对病原真菌造成影响;通过根系化学物质释放、营养元素调节、侵染条件差异等对丛枝菌根真菌造成影响;通过根际沉积物和凋落物等对土壤微生物群落造成影响。禾草内生真菌产生的生物碱能提高宿主植物对包括昆虫在内草食动物采食的抗性,影响病原菌的侵入、定殖和扩展;根组织分泌物中包含次生代谢产物能够抑制菌根真菌、土传病原真菌及其它土壤微生物的侵染与群落组成;也可能通过次生代谢物影响禾草的其它抗性。因此,禾草内生真菌在植物-微生物系统中的作用应该给予更多的关注和深入研究。     

More than 400 million years of evolution and some plants still can't make it on their own: plant stress tolerance via fungal symbiosis

All plants in natural ecosystems are thought to be symbioticwith mycorrhizal and/or endophytic fungi. Collectively, thesefungi express different symbiotic lifestyles ranging from parasitismto mutualism. Analysis of Colletotrichum species indicates thatindividual isolates can express either parasitic or mutualisticlifestyles depending on the host genotype colonized. The endophytecolonization pattern and lifestyle expression indicate thatplants can be discerned as either disease, non-disease, or non-hosts.Fitness benefits conferred by fungi expressing mutualistic lifestylesinclude biotic and abiotic stress tolerance, growth enhancement,and increased reproductive success. Analysis of plant–endophyteassociations in high stress habitats revealed that at leastsome fungal endophytes confer habitat-specific stress toleranceto host plants. Without the habitat-adapted fungal endophytes,the plants are unable to survive in their native habitats. Moreover,the endophytes have a broad host range encompassing both monocotsand eudicots, and confer habitat-specific stress tolerance toboth plant groups. Key words: Colletotrichum, fungal endophytes, stress tolerance, symbiosis, symbiotic lifestyle Received 19 June 2007; Revised 25 November 2007 Accepted 30 November 2007     

Do endophytic fungi grow through their hosts systemically?

Endophyte fungi are ubiquitous within vascular plants and recent evidence suggests that they have a number of effects on other organisms that attack those plants, such as insects and pathogens. Endophytes produce an array of metabolites in culture and it is possible that these fungi could be used in targeted programmes of application to plants, to provide a degree of pest protection. Such programmes would be most effective if the fungi grew systemically through their hosts. To date, evidence for systemic growth is equivocal and the aim of this study was to determine whether systemic growth occurs, through a detailed study of endophytes in one host plant species. We isolated a number of endophytes from the forb Silene dioica and examined fungal interactions in dual culture. We found very little evidence for any systemic growth within leaves and none within plants. Antagonistic interactions between fungi were extremely common, suggesting that any systemic effects of these fungi on other organisms are likely to be due to chemical movement, not fungal growth.     

Epichloë fungal endophytes and the formation of synthetic symbioses in Hordeeae (=Triticeae) grasses

This review examines two classes of organism that live in symbiosis; grasses, and fungi. Specifically it deals with grasses of the tribe Hordeeae (formerly Triticeae) of the subfamily Poöideae and the Epichloë fungi of family Clavicipitaceae. Epichloë endophytes, particularly asexual forms, have important roles in pastoral agricultural systems in the Americas, Australia, and New Zealand. Selected strains add value to some grass-based forage systems by providing both biotic and abiotic stress resistance. The importance of cereal grasses such as wheat, barley, rye, and oats to human and animal nutrition and indeed to the foundation and maintenance of human civilization is well documented. Both organism classes, Epichloë endophytes and cereal grasses, are of great importance in their own contexts. Here, we seek to review these two classes of organism and examine the possibility of bringing them together in symbiosis with the ultimate goal of improving cereal production systems.     

Multitrophic interactions among fungal endophytes,bees, and <Emphasis Type="Italic">Baccharis dracunculifolia</Emphasis>: resin tapering for propolis production leads to endophyte infection

The tropics are known for their high diversity of plants, animals, and biotic interactions, but the role of the speciose endophytic fungi in these interactions has been mostly neglected. We report a unique interaction among plant sex, bees, and endophytes on the dioecious shrub, Baccharis dracunculifolia (Asteraceae). We assessed whether there was an association between resin collection by bees and fungal endophytes considering the host plant sex. We hypothesized that resin collection by the Africanized honey bee, Apis mellifera L. (Apidae) could favor the entry of endophytes in B. dracunculifolia. Specifically, we tested the hypotheses that (1) bees damage the leaf buds of female and male plant at different proportions; (2) damage on leaf buds increases the richness of endophytic fungi; (3) endophyte richness differs between female and male plants; and (4) in vitro growth of endophytes depends on the sex of the plant individual from which the resin was extracted. Endophyte richness and proportion of leaf bud damage did not vary between the plant sexes. However, species similarity of endophytes between female and male plants was 0.33. Undamaged leaf buds did not show culturable endophytes, with all fungi exclusively found in damaged leaf buds. Endophyte composition changed with the plant sex. The endophytes exclusively found in female plants did not develop in the presence of male resin extract. These findings highlight that resin collection by A. mellifera for propolis production favors the entry of endophytic fungi in B. dracunculifolia. Additionally, endophyte composition and growth are influenced by plant sex.     

Preliminary insights into the evolutionary relationships of aquatic hyphomycetes and endophytic fungi

Aquatic hyphomycetes play a key role in leaf litter decomposition and are mediators of organic matter turnover in streams. Molecular studies have shown that some aquatic fungi are also plant endophytes, however, more evidence is needed to evaluate their multiple ecological abilities. To date, little information is available on fungal lineages that might have undergone convergent evolution to adapt to multiple ecological modes. We examined the phylogenetic relationships and evolutionary divergences of aquatic hyphomycetes, endophytic aquatic hyphomycetes and other fungal endophytes of riparian/terrestrial plants by analyzing ITS1-5.8S-ITS2 sequences retrieved from the National Center for Biotechnology Information (NCBI). Sequences with close phylogenetic affinity to aquatic fungi can occur as endophytes of terrestrial plants or in soil far from streams. To fully understand the ecological impact of aquatic hyphomycetes, we need to document and interpret their niches more broadly.