丛枝菌根（AM）与植物的抗逆性

菌根是土壤中的菌根真菌与高等植物的根系形成的一种联合体 ,是自然界中一种普遍的植物共生现象。除十字花科、莎草科、藜科等少数几个科不能或不易形成菌根外 ,大多数植物包括苔藓、蕨类、裸子植物、被子植物都能形成菌根。 AM是其中的一类 ,也是目前研究较多的一类。AM的内外生菌丝不仅增加了根系的吸收面积 ,还能分泌多种有益物质。所以 ,AM对植物养分、水分的吸收与运输 ,对植物抵抗各种胁迫是十分有益的。1　AM与植物的抗旱性随着全球干旱面积的不断增加 ,淡水资源的日益减少 ,干旱研究已受到人们极大的关注。由于菌根的特殊作用和…     

Impact on Arbuscular Mycorrhiza Formation of Pseudomonas Strains Used as Inoculants for Biocontrol of Soil-Borne Fungal Plant Pathogens

The arbuscular mycorrhizal symbiosis, a key component of agroecosystems, was assayed as a rhizosphere biosensor for evaluation of the impact of certain antifungal Pseudomonas inoculants used to control soil-borne plant pathogens. The following three Pseudomonas strains were tested: wild-type strain F113, which produces the antifungal compound 2,4-diacetylphloroglucinol (DAPG); strain F113G22, a DAPG-negative mutant of F113; and strain F113(pCU203), a DAPG overproducer. Wild-type strain F113 and mutant strain F113G22 stimulated both mycelial development from Glomus mosseae spores germinating in soil and tomato root colonization. Strain F113(pCU203) did not adversely affect G. mosseae performance. Mycelial development, but not spore germination, is sensitive to 10 μM DAPG, a concentration that might be present in the rhizosphere. The results of scanning electron and confocal microscopy demonstrated that strain F113 and its derivatives adhered to G. mosseae spores independent of the ability to produce DAPG.     

福建红树林植物丛枝菌根侵染研究

2010年5月和12月,对福建沿海3个红树林生长区(洛阳江、九龙江口、漳江口)的红树林植物丛枝菌根（AM）侵染状况进行研究。结果表明：（1）红树林生长区中6种植物根内均发现AMF侵染结构,其中桐花树、秋茄、鱼藤和芦苇的丛枝为Arum（疆南星）型;（2）6种植物的丛枝菌根侵染率差异较大,老鼠簕的侵染率最高,鱼藤最低;（3）桐花树和秋茄的丛枝菌根侵染率呈显著差异,而其在不同生长区之间无差异;（4）桐花树和秋茄的丛枝菌根侵染率在不同时间呈显著差异,而钝草的丛枝菌根侵染率在不同时间的差异不显著。     

丛枝菌根在退化土壤恢复中的生态学作用

土壤退化(包括土壤侵蚀、贫瘠化、盐碱化、沙化、酸化)不仅为全球所关注,而且是关系到我国农业可持续发展的重大问题.全球1.3×108km2的总土地面积中,因人为原因引起的退化面积为2.0×107km2,这些退化土壤中,耕地近5×108ha,约占总耕地面积的1/3.     

3种农业措施对柑橘丛枝菌根发育的影响

研究了土施N肥(2L 0.5%尿素)、覆草(5~6cm厚杂草)和翻耕(20cm表层土翻耕2次)三种措施,对田间条件下的国庆1号/枳和国庆4号/枳的菌根侵染率和孢子密度的影响。结果表明,覆草极显著地提高了2种柑橘根系的孢子密度,而对菌根侵染率无显著影响;施N肥极显著降低2种柑橘的孢子密度;翻耕极显著抑制了2种柑橘的菌根侵染率。2种柑橘的根系菌根侵染率和孢子密度间都存在显著或极显著正相关。     

丛枝菌根真菌对连翘幼苗抗旱性的影响

采用集球囊霉（Glomus fasciculatum Gerd.＆ Trappe emend.Walker ＆ Koske）、缩球囊霉（Glomus constrictum Trappe）单独接种和混合接种于连翘（Forsythia suspensa（Thunb.）Vahl）幼苗,研究丛枝菌根真菌对连翘抗旱性的影响.结果表明：在干旱胁迫条件下,随着菌根侵染率的提高,连翘幼苗叶绿素和脯氨酸含量增加,SOD活性增强,丙二醛含量和膜透性降低,苗木枯死率下降.菌根真菌通过促进苗木快速累积游离脯氨酸,提高SOD酶活性,减缓干旱对细胞膜的破坏,延缓了植物受伤害的速度,提高连翘幼苗的抗旱性;在不同接种处理间,混合接种效果最好,其次为缩球囊霉单独接种.     

蕨类植物的VA菌根与蕨类植物系统演化关系的研究

通过对云南热带、亚热带生长的２５６种蕨类植物ＶＡ菌根的调查,发现蕨类植物ＶＡ菌根营养者所占的比例低于被子植物;在真蕨类植物中,植物具有由ＶＡ菌根营养经兼性ＶＡ菌根营养向自养方向进化的趋势。     

VA菌根在植物生态学研究中的意义

植物生态学是研究植物和环境之间相互作用关系规律的科学。土壤、地形、气候、各种生物都是重要的环境因素 ,它们影响着植物群落的区系组成、结构、空间分布、物种多样性以及生态系统的稳定性、生产力等 ,因而在生态学研究中受到了充分的重视[2 0 ] 。然而植物与土壤微生物之间的关系 ,尤其是植物与ＶＡ菌根菌形成的共生体 ,即ＶＡ菌根在植物生态学研究中则很少有人注意。近 30年来的发现和研究证实 ,ＶＡ菌根菌与植物形成的ＶＡ菌根共生关系也是植物生态学研究中不可忽视的一种重要关系 ,这是因为 :①在自然生态系统中 ,80 %的维管束植物具…     

丛枝菌根在退化土壤恢复中的生态学作用

土壤退化 (包括土壤侵蚀、贫瘠化、盐碱化、沙化、酸化 )不仅为全球所关注 ,而且是关系到我国农业可持续发展的重大问题。全球 1.3× 10 8ｋｍ2 的总土地面积中 ,因人为原因引起的退化面积为 2 0×10 7ｋｍ2 ,这些退化土壤中 ,耕地近 5× 10 8ｈａ ,约占总耕地面积的 1/ 3。我国南方丘陵区土壤退化问题也突出 (水土流失面积 8 0× 10 7ｈａ ,养分贫瘠化 1 9×10 7ｈａ ,污染土壤 3 2× 10 6ｈａ ,酸化土壤 3 2×10 6ｈａ) ,因而探讨恢复和重建退化土壤的途径已成为该地区农业持续发展的重要内容[5] 。菌根 (ｍｙｃｏｒｒｈｉｚａ)是土…     

Arbuscular Mycorrhiza and Petroleum-Degrading Microorganisms Enhance Phytoremediation of Petroleum-Contaminated Soil

While plants can phytoremediate soils that are contaminated with petroleum hydrocarbons, adding microbes to remediate contaminated sites with petroleum-degrading microorganisms and arbuscular mycorrhizal fungi (AMF) is not well understood. The phytoremediation of Arabian medium crude oil (ACO) was done with a Lolium multiflorum system inoculated with an AMF (Glomus intraradices) and a mixture of petroleum-degrading microorganisms—the bacterium, Sphingomonas paucimobilis (Sp) and the filamentous fungus, Cunninghamella echinulata (Ce, SpCe)—or with a combination of microorganisms (AMF + SpCe). Based on an earlier study on screening plants for phytoremediation of ACO, L. multiflorum (Italian ryegrass) was selected for its tolerance and rapid growth response (Alarcón, 2006 Alarcón, A. 2006. “The physiology of mycorrhizal-colonized Lolium multiflorum in the phytoremediation of petroleum hydrocarbons contaminated soil. PhD Dissertation”. College Station, TX: Texas A&M University.  [Google Scholar]). The plants were exposed to ACO-contaminated soil (6000 mg kg^?1) for 80 d under greenhouse conditions. A modified Long Ashton Nutrient Solution (LANS) was supplied to all treatments at 30 μg P mL^?1, except for a second, higher P, control treatment at 44 μg P mL^?1. Inoculation with AMF, SpCe, or AMF + SpCe resulted in significantly increased leaf area as well as leaf and pseudostem dry mass as compared to controls at 30 μg P mL^?1. Populations of bacteria grown on a nitrogen-free medium and filamentous fungi increased with AMF + SpCe and SpCe treatments. The average total colonization and arbuscule formation of AMF-inoculated plants in ACO-contaminated soil were 25% and 8%, respectively. No adverse effects were caused by SpCe on AMFcolonization. Most importantly, ACOdegradation was significantly enhanced by the addition of petroleum-degrading microorganisms and higher fertility controls, as compared to plants at 30 μg P mL^?1. The highest ACOdegradation (59%) was observed with AMF + SpCe. The phytoremediation of ACO was also enhanced by single inoculation of AMF or SpCe. The effect of AMF and petroleum-degrading microorganisms on plant growth and ACOdegradation was not attributable to differences in proline, total phenolics, nitrate reductase levels, or variation in plant–gas exchange.     

Carbon Uptake and the Metabolism and Transport of Lipids in an Arbuscular Mycorrhiza

Both the plant and the fungus benefit nutritionally in the arbuscular mycorrhizal symbiosis: The host plant enjoys enhanced mineral uptake and the fungus receives fixed carbon. In this exchange the uptake, metabolism, and translocation of carbon by the fungal partner are poorly understood. We therefore analyzed the fate of isotopically labeled substrates in an arbuscular mycorrhiza (in vitro cultures of Ri T-DNA-transformed carrot [Daucus carota] roots colonized by Glomus intraradices) using nuclear magnetic resonance spectroscopy. Labeling patterns observed in lipids and carbohydrates after substrates were supplied to the mycorrhizal roots or the extraradical mycelium indicated that: (a) ¹³C-labeled glucose and fructose (but not mannitol or succinate) are effectively taken up by the fungus within the root and are metabolized to yield labeled carbohydrates and lipids; (b) the extraradical mycelium does not use exogenous sugars for catabolism, storage, or transfer to the host; (c) the fungus converts sugars taken up in the root compartment into lipids that are then translocated to the extraradical mycelium (there being little or no lipid synthesis in the external mycelium); and (d) hexose in fungal tissue undergoes substantially higher fluxes through an oxidative pentose phosphate pathway than does hexose in the host plant.     

Suppressive Effect of Trehalose on Acrylamide Formation from Asparagine and Reducing Saccharides

The influence of saccharides on the formation of acrylamide (AcA) was investigated. The reducing saccharides reacted with asaparagine to form AcA, but the non-reducing saccharides, except sucrose, gave no AcA. AcA formation from a mixture containing glucose and asaparagaine was suppressed by the non-reducing saccharides, especially trehalose (76% suppression) and neotrehalose (75% suppression). Glucose is heat-degraded into pyruvaldehyde and 5-hydroxymethyl-2-furfural in the water system. The degradation products react with asparagines to generate AcA. Trehalose appears to inhibit not only the formation of these intermediates and asparagines for AcA, but also the AcA formation from these intermediates.     

Arbuscular Mycorrhiza: Studies on the Geosiphon Symbiosis Lead to the Characterization of the First Glomeromycotan Sugar Transporter

The intimate arbuscular mycorrhiza (AM) association between roots and obligate symbiotic Glomeromycota (‘AM fungi’) ‘feeds’ about 80% of land plants. AM forming fungi supply land plants with inorganic nutrients and have an enormous impact on terrestrial ecosystems. In return, AM fungi obtain up to 20% of the plant-fixed CO₂, putatively as monosaccharides. In a recent work we have reported the characterization of the first glomeromycotan monosaccharide transporter, GpMST1, and its gene sequence. We discuss that AM fungi might take up sugars deriving from plant cell-wall material. The GpMST1 sequence delivers valuable data for the isolation of orthologues from other AM fungi and may eventually lead to the understanding of C-flows in the AM.Key Words: arbuscular mycorrhiza, Geosiphon symbiosis, monosaccharide transporter, hexosesThe arbuscular mycorrhiza (AM) as an outstanding terrestrial plant symbiosis directly and indirectly is a driver of most terrestrial ecosystems. It is formed by ∼80% of land plants and by obligate symbiotic fungi of the phylum Glomeromycota.¹ The glomeromycotan fungi usually are called ‘arbuscular mycorrhizal (AM) fungi’, or ‘AMF’, and obviously play an enormous ecological (and economical) role. Most land plants and glomeromycotan fungi are ‘joint systems’, forming the intimate AM.² By this fact, statements like that of the BEG (European Bank of Glomeromycota) committee (1993): “The study of plants without their mycorrhizas is the study of artefacts; the majority of plants, strictly speaking, do not have roots—they have mycorrhizas” were provoked. AM fungi supply the vast majority of land plants with inorganic nutrients, mainly phosphorous, but also nitrogen, trace elements, and water. In return, they obtain up to >20% of the photosynthetically fixed CO₂ as carbohydrates from the plants.³ It was calculated that, each year, 5 billion tons of carbon are transferred from plants to fungi (and therefore partly get deposited in the soil) via the AM symbiosis. AM fungi therefore represent a large sink for atmospheric CO₂ on our planet and play a role in C-deposition in the soil.     

金银花根系VAM真菌侵染过程观察

在金银花生长季节,从西北农林科技大学北校区药用植物园采集金银花根系及根际土壤,采用形态学方法观察研究了VAM真菌侵染其根系的过程,并对其孢子进行了初步的形态学分类。结果表明:(1)VAM真菌侵染金银花根系时,先形成附着胞,然后入侵到皮层细胞,在根内形成线性菌丝、圈状菌丝;菌丝末端产生泡囊;在较粗的菌丝上产生丛枝状菌丝,而且VAM胞内菌丝主干可以穿越相邻的2个皮层细胞,在皮层中连续形成丛枝;VAM菌丝形成丛枝时,首先是胞内菌丝上膨大产生乳状突起,而后在乳状突起上产生较粗的丛枝柄,最后在这些丛枝柄上产生极细的丛枝状菌丝形成成熟的丛枝结构。(2)VAM真菌菌丝在金银花皮层细胞中,有伸展状态、菌丝圈及丛枝状态,所以金银花与VAM真菌形成的菌根是混合型菌根。(3)金银花根际土壤中至少存在3种类型的VAM真菌孢子,因此认为金银花至少可与3种VAM真菌共生。(4)金银花种植地土壤有效磷含量(6.6mg/kg)显著高于对照空地土壤有效磷含量(3.5mg/kg);金银花生长旺盛季(4月下旬到5月中旬)VAM真菌对其根系的侵染率高达81%。     

植物菌根共生磷酸盐转运蛋白

大多数植物能和丛枝菌根（arbuscular mycorrhiza, AM）真菌形成菌根共生体。AM能够促进植物对土壤中矿质营养的吸收,尤其是磷的吸收。磷的吸收和转运由磷酸盐转运蛋白介导。总结了植物AM磷酸盐转运蛋白及其结构特征,分析其分类及系统进化,并综述了AM磷酸盐转运蛋白介导的磷的吸收和转运过程及其基因的表达调控。植物AM磷酸盐转运蛋白属于Pht1家族成员,它不仅对磷的吸收和转运是必需的,而且对AM共生也至关重要,为进一步了解菌根形成的分子机理及信号转导途径提供了理论基础。     

Improvement of Arbuscular Mycorrhiza Development by Inoculation of Soil with Phosphate-Solubilizing Rhizobacteria To Improve Rock Phosphate Bioavailability ((sup32)P) and Nutrient Cycling

The interactive effect of phosphate-solubilizing bacteria and arbuscular mycorrhizal (AM) fungi on plant use of soil P sources of low bioavailability (endogenous or added as rock phosphate [RP] material) was evaluated by using soil microcosms which integrated (sup32)P isotopic dilution techniques. The microbial inocula consisted of the AM fungus Glomus intraradices and two phosphate-solubilizing rhizobacterial isolates: Enterobacter sp. and Bacillus subtilis. These rhizobacteria behaved as "mycorrhiza helper bacteria" promoting establishment of both the indigenous and the introduced AM endophytes despite a gradual decrease in bacterial population size, which dropped from 10(sup7) at planting to 10(sup3) CFU g(sup-1) of dry rhizosphere soil at harvest. Dual inoculation with G. intraradices and B. subtilis significantly increased biomass and N and P accumulation in plant tissues. Regardless of the rhizobacterium strain and of the addition of RP, AM plants displayed lower specific activity ((sup32)P/(sup31)P) than their comparable controls, suggesting that the plants used P sources not available in their absence. The inoculated rhizobacteria may have released phosphate ions ((sup31)P), either from the added RP or from the less-available indigenous P sources, which were effectively taken up by the external AM mycelium. Soluble Ca deficiency in the test soil may have benefited P solubilization. At least 75% of the P in dually inoculated plants derived from the added RP. It appears that these mycorrhizosphere interactions between bacterial and fungal plant associates contributed to the biogeochemical P cycling, thus promoting a sustainable nutrient supply to plants.     

Influence of Arbuscular Mycorrhiza and Phosphorus Supply on Polyamine Content, Growth and Photosynthesis of Plantago lanceolata

A greenhouse pot experiment with different phosphorus supply was conducted to study growth, photosynthesis and free polyamine (PA) content in Plantago lanceolata L. plants in relation to arbuscular mycorrhizal (AM) colonization. Inoculum of Glomus fasciculatum (BEG 53) was used. Inoculated plants had high colonization intensities which were related to the P supply. Non-mycorrhizal (NM) plants showed a typical yield response curve for P availability. Dry masses of mycorrhizal (M) plants were higher at the lowest soil P content than those of NM plants, but the opposite was found at the highest P supply. P contents in M plants were always higher. There were no differences in chlorophyll (Chl) concentrations (except the lowest soil P content) and ratios of variable to maximum Chl fluorescence (Fv/Fm) values between M and NM plants, whereas M plants had higher ratios of leaf area to fresh mass (A/f.m.) at low soil P contents and they had significantly higher CO₂ fixation capacities per unit leaf area. Free putrescine (Put), spermidine (Spd) and spermine (Spm) contents in NM plants were usually highest at the lowest P supply. The ratios of Put/(Spd+Spm) were identical in M and NM leaves. They were significantly higher, however, in NM roots at the two low P doses. It is concluded, that a P nutritional status might exist, below which PA concentrations and ratio are increased drastically, possibly indicating P deficiency or a certain state of plant development with a higher demand for AM symbiosis. This revised version was published online in July 2006 with corrections to the Cover Date.     

Effect of Phosphate and Other Anions on Trimethylarsine Formation by Candida humicola

Phosphate inhibited the formation of trimethylarsine from arsenite, arsenate, and monomethylarsonate, but not from dimethylarsinate, by growing cultures of Candida humicola. Phosphite suppressed trimethylarsine production by growing cultures from monomethylarsonate but not from arsenate and dimethylarsinate, and hypophosphite caused a temporary inhibition of both proliferation and the conversion of these three arsenic sources to trimethylarsine. Resting cells of C. humicola derived from cultures grown in arsenic-free media generated the volatile arsenical only after a lag phase. High antimonate concentrations reduced the rate of conversion of arsenate to trimethylarsine by resting cells, but nitrate was without effect.     

The Vesicular Arbuscular Mycorrhiza Associated with Three Cultivars of Rice (Oryza sativa L.)

The present study deals with the occurrence of vesicular arbuscular mycorrhizal fungi in three cultivars of rice in Barak valley. Three cultivars of rice were Pankaj, Malati and Ranjit. The results revealed the association of VAM fungi in all the cultivars of rice. The association was maximum in Pankaj cultivar followed by Malati, and Ranjit, respectively, in all the three sampling phases. All the three cultivars of rice crop showed maximum soil spore population and number of VAM fungal species at the harvesting phase (135 DAS) and minimum at the phase of maturation (90 DAS). Glomus species were found dominating followed by Acaulospora species. Glomus microcarpum, Glomus claroideum, Glomus mosseae and Acaulospora scrobiculata were found in all the three fields.