内生真菌和内生细菌接种对雷公藤生长和次生代谢产物积累的影响

为探究内生真菌与内生细菌对雷公藤(Tripterygium wilfordii)的生长和次生代谢产物积累的相互作用,用内生真菌NS33、NS6和内生细菌LG3、LY1单独或跨界联合接种雷公藤,对雷公藤的生长和雷公藤甲素、雷公藤红素合成进行了研究。结果表明,单独或混合培养的菌株具有分泌铁载体、吲哚乙酸(IAA)和溶磷能力,对种子萌发、芽伸长和根系活力有显著促进作用。接种菌株NS33、NS6、NS6-LG3和NS6-LY1均显著促进了雷公藤组培苗的生长。单独或联合接种菌株均能显著提高雷公藤组培苗雷公藤甲素和雷公藤红素的积累,其中NS33-LG3和LG3的作用最显著。菌株NS33与LG3能够协同促进IAA的分泌、小麦幼苗根系活力和雷公藤红素的积累;菌株NS6与LY1协同提高了雷公藤组培苗的高度、质量和雷公藤红素的积累。因此,内生真菌与内生细菌联合接种对雷公藤生长和次生代谢产物积累具有一定的协同效应,显示出实际应用潜力。     

Isolation of micropropagated strawberry endophytic bacteria and assessment of their potential for plant growth promotion

Twenty endophytic bacteria were isolated from the meristematic tissues of three varieties of strawberry cultivated in vitro, and further identified, by FAME profile, into the genera Bacillus and Sphingopyxis. The strains were also characterized according to indole acetic acid production, phosphate solubilization and potential for plant growth promotion. Results showed that 15 strains produced high levels of IAA and all 20 showed potential for solubilizing inorganic phosphate. Plant growth promotion evaluated under greenhouse conditions revealed the ability of the strains to enhance the root number, length and dry weight and also the leaf number, petiole length and dry weight of the aerial portion. Seven Bacillus spp. strains promoted root development and one strain of Sphingopyxis sp. promoted the development of plant shoots. The plant growth promotion showed to be correlated to IAA production and phosphate solubilization. The data also suggested that bacterial effects could potentially be harnessed to promote plant growth during seedling acclimatization in strawberry.     

Effects on winter wheat seedling growth by toxin-producing rhizobacteria

Summary Root-colonizing pseudomonads capable of inhibiting seedling winter wheat (Triticum aestivum L.) root growth in an agar seedling bioassay also significantly inhibited wheat root growth in vermiculite; however, the inhibitory trait is quite labile in laboratory culturing. The extent of inhibition in both the agar and vermiculite medium depended on inoculum level. These pseudomonads were found to produce a toxin capable of inhibiting growth ofEscherichia coli C-la andBacillus subtilis. Field isolates that strongly inhibit growth of indicator bacteria also inhibited root growth. Toxin production by the bacteria appeared necessary for inhibition of root growth and indicator bacteria as toxin-negative (TOX^–) mutants no longer inhibited either. Antibiosis towardsE. coli as well as wheat seedling root inhibition in agar was reversed by L-methionine, providing further evidence that a toxin, produced by these organisms, is involved in growth retardation.Contribution in cooperation with the College of Agric. Res. Center, Washington State Univ., Pullman, WA 99164. Scientific Paper No. 6837.     

乌头产吲哚乙酸内生细菌遗传多样性、抗逆性及其对水稻幼苗生长的影响

[目的]探究乌头产吲咮乙酸(IAA)内生细菌的遗传多样性、溶磷解钾能力、抗逆能力及其对水稻幼苗生长的影响,为道地产区乌头产业可持续发展提供科技支撑.[方法]从健康乌头植株分离可培养内生细菌,采用Salkowski比色法测定内生细菌产IAA能力,16S rDNA限制性片段长度多样性(16S rDNA-RFLP)及16S ...     

Alleviation of salt stress by plant growth regulators and IAA producing bacteria in wheat

The action of phytohormone producing bacteria and plant growth regulators on germination and seedling growth of wheat under saline conditions were studied. Seed dormancy enforced by salinity (100 mM NaCl) was substantially alleviated and the germination was promoted by gibberellin, auxin, zeatin, and ethephon from 54 to 97%. The IAA producing bacterial strains Pseudomonas aureantiaca TSAU22, Pseudomonas extremorientalis TSAU6 and Pseudomonas extremorientalis TSAU20 significantly increased seedling root growth up to 25% in non-salinated conditions and up to 52% at 100 mM NaCl, compared to control plants. It is concluded that growth regulators considerably alleviated salinity-induced dormancy of wheat seeds. The facts mentioned above make it possible to recommend root colonizing bacteria that produce phytohormone to alleviate salt stress of wheat grown under conditions of soil salinity.     

Screening of <i>Bacillus subtilis</i> HAAS01 and Its Biocontrol Effect on <i>Fusarium</i> wilt in Sweet Potato

Fusarium wilt, a disease caused by Fusarium oxysporum f.sp batatas (Fob) is an important disease in sweet potato production. Using endophytic bacteria for biological control of sweet potato diseases is one of the important ways. A Bacillus subtilis with antagonistic effect on Fusarium wilt of sweet potato was isolated from soil by confrontation culture. According to the biological characteristics, 16S rDNA sequence analysis, and physiological and biochemical analysis, the Bacillus subtilis HAAS01 was named. A pot experiment was conducted for the biological control experiment of strain HAAS01, and the endogenous hormone content, antioxidant enzyme activity, soluble protein content, and related gene expressions of sweet potato plants were detected. The results showed that the HAAS01 strain could promote the production of endogenous hormones and resist the infection of plant diseases together with defensive enzymes and upregulation of related gene expressions. In summary, Bacillus subtilis HAAS01 was effective in controlling Fusarium wilt of sweet potato and has potential for application and development.     

Characterization of Novel Plant Growth Promoting Endophytic Bacterium <Emphasis Type="Italic">Achromobacter xylosoxidans</Emphasis> from Wheat Plant

Nine diazotrophic bacteria were isolated from surface-sterilized roots and culms of wheat variety Malviya-234, which is grown with very low or no inputs of nitrogen fertilizer. Out of the nine bacteria, four showed indole acetic acid (IAA) production, and five were positive for P solubilization. One isolate, WM234C-3, showed appreciable level of nitrogenase activity, IAA production, and P solubilization ability, and was further characterized with a view to exploiting its plant growth promoting activity. Based on 16S rDNA sequence analysis, this isolate was identified as Achromobacter xylosoxidans. Diazotrophic nature of this particular isolate was confirmed by Western blot analysis of dinitrogenase reductase and amplification of nifH. Analysis of the nifH sequence showed close homology with typical diazotrophic bacteria. Endophytic nature and cross-infection ability of WM234C-3 were tested by molecular tagging with gusA fused to a constitutive promoter followed by inoculation onto rice seedlings in axenic conditions. At 21 days after inoculation, the roots showed blue staining, the most intense color being at the emergence of lateral roots and root tips. Microscopic observation confirmed colonization of gus-tagged WM234C-3 in the intercellular spaces of cortical as well as vascular zones of roots. Inoculation of gus-tagged WM234C-3 to rice plants resulted in significant increase in root/shoot length, fresh weight, and chlorophyll a content. Plant growth promoting features coupled with cross-infection ability suggest that this endophytic bacterium may be exploited as agricultural agent for various crops after a thorough and critical pathogenicity test.     

Application of endophytic bacteria for controlling anthracnose disease (Colletotrichum lindemuthianum) on bean plants

Over 100 endophytic bacterial isolates were isolated from surface-sterilised roots of the Fabaceae family in East Azerbaijan farms. These isolates were screened for their in vitro biocontrol activity against Colletotrichum lindemuthianum by dual culture technique using potato dextrose agar (PDA) medium. Eight bacterial isolates (Bacillus subtilis subsp. subtilis, Bacillus atrophaeus, B. tequilensis, B. subtilis subsp. spizizenii, Streptomyces cyaneofuscatus, S. flavofuscus, S. parvus, S. acrimycini) showed promising inhibition on mycelial growth of C. lindemuthianum , and thus, these isolates were selected for greenhouse experiments. The disease control rate using these selected endophytic bacteria was varied from 40 to 76.80% in greenhouse without any negative effects on different growth performance, suggesting that these selected endophytic bacteria are potential to be developed as biocontrol agents.     

Growth promotion effects of the endophyte <Emphasis Type="Italic">Acinetobacter johnsonii</Emphasis> strain 3-1 on sugar beet

An endophytic bacteriumn identified as Acinetobacter johnsonii strain 3–1 was isolated from surface-sterilized roots of Beta vulgaris. Its effect on sugar beet seedling growth was studied using pot assays and field experiments. This strain promoted beet seedling growth following seed inoculation by seed dipping. Plant height and dry weight of beet increased by 19% and 69%, respectively, compared with controls. Strain 3–1 exhibited the ability to increase absorption of N, P, K, and Mg elements from soil and increase the content of vitamins B and C, and protein within beet. In addition, the strain also produced a phytohormone-auxin, produced nearly twice as much IAA as that produced by strain 2–2, and was able to solubilize phosphates. The concentration of dissolved P in the medium was 180.5 mg L⁻¹ after 4 days of incubation. In field experiments, strain 3–1 significantly increased the content of sucrose, fructose, and the yield of the beet. The growth-promoting properties of Acinetobacter johnsonii strain 3–1 indicates that this promising isolate merits further investigation into its symbiosis with beet plants and its potential application in agriculture.     

Native bacterial endophytes promote host growth in a species-specific manner; phytohormone manipulations do not result in common growth responses

Background

All plants in nature harbor a diverse community of endophytic bacteria which can positively affect host plant growth. Changes in plant growth frequently reflect alterations in phytohormone homoeostasis by plant-growth-promoting (PGP) rhizobacteria which can decrease ethylene (ET) levels enzymatically by 1-aminocyclopropane-1-carboxylate (ACC) deaminase or produce indole acetic acid (IAA). Whether these common PGP mechanisms work similarly for different plant species has not been rigorously tested.

Methodology/ Principal Findings

We isolated bacterial endophytes from field-grown Solanum nigrum; characterized PGP traits (ACC deaminase activity, IAA production, phosphate solubilization and seedling colonization); and determined their effects on their host, S. nigrum, as well as on another Solanaceous native plant, Nicotiana attenuata. In S. nigrum, a majority of isolates that promoted root growth were associated with ACC deaminase activity and IAA production. However, in N. attenuata, IAA but not ACC deaminase activity was associated with root growth. Inoculating N. attenuata and S. nigrum with known PGP bacteria from a culture collection (DSMZ) reinforced the conclusion that the PGP effects are not highly conserved.

Conclusions/ Significance

We conclude that natural endophytic bacteria with PGP traits do not have general and predictable effects on the growth and fitness of all host plants, although the underlying mechanisms are conserved.     

Features of <Emphasis Type="Italic">Bacillus subtilis</Emphasis> IMB B-7023 and its streptomycin-resistant strain

Features of phosphate-mobilizing bacteria Bacillus subtilis IMB B-7023 and its streptomycin-resistant strain were investigated. While cultivated in medium with glucose and glycerophosphate, the growth rate of the antibiotic-marked strain was approximately similar to this parameter for Bacillus subtilis IMB B-7023 but cell sizes were 1.3-fold less. Both strains significantly stimulated the germinating of plant seeds, attached to their roots, and insignificantly differed in antagonistic activity toward phytopathogens and quantitative content of cell fatty acids and phosphatase activity. Streptomycin-resistant strain may be used for monitoring of Bacillus subtilis introduced to agroecosystem.     

Multifunctional potential of endophytic and rhizospheric microbial isolates associated with <Emphasis Type="Italic">Butia purpurascens</Emphasis> roots for promoting plant growth

The functional diversity of endophytic and rhizospheric microorganisms associated with the promotion of plant growth includes increased availability of plant nutrients, phytohormone synthesis and phytopathogen suppression. We used the hypothesis that the unknown root and rhizospheric community associated with the Butia purpurascens palm, an endemic species of the Cerrado, could be composed of microbiota with great functional diversity. Thus, the potential of the isolates of this community for four functional traits was evaluated: solubilization of calcium phosphate (CaHPO₄) and iron phosphate (FePO₄), synthesis of indoleacetic acid (IAA) and suppression of seed- and fruit-spoilage fungi of B. purpurascens. A total of 166 bacterial isolates, most belonging to the phylum Proteobacteria (94%), and 46 fungal isolates (Ascomycota) were tested. None of the isolates showed the four functional traits tested, but 72% presented two traits (CaHPO₄ solubilization and IAA synthesis). Fifteen fungi (27% of the isolates) presented only the trace for IAA, whereas the capacity for antibiosis was observed in only eight bacteria. CaHPO₄-solubilization capacity was evidenced by all bacterial isolates and by some fungal isolates. The functional trait for IAA production was present in all isolates, and production levels were significantly above 100 μg mL^?1 for some bacteria. Isolates of the genus Bacillus efficiently suppressed the growth of spoilage fungi tested, with relative inhibition rates reaching levels higher than 60% when using Bacillus subtilis. These results attest to the multifunctionality of the endophytic and rhizospheric isolates of B. purpurascens for the promotion of plant growth. This is the first study that sought to identify the root endophytic and rhizospheric microbiota associated with the B. purpurascens palm for the bioprospection of species with functional traits related to the promotion of plant growth, thus opening the way for in vivo tests in plants of commercial or ecological interest.     

番茄内生菌的分离鉴定及菌株FQ-G3抗病促生特性

由灰葡萄孢(Botrytis cinerea)引起的灰霉病是番茄生产中最重要的病害之一,当前使用的杀菌剂因药物残留、病原菌抗药性及食品安全等原因逐渐受到限制。因此,利用拮抗微生物的生物防治逐渐成为灰霉病防控的有效策略。【目的】从番茄植株体内筛选具有抗病促生特性内生菌株并对其生防潜力进行评估,为开发番茄灰霉病生物防治新策略提供理论依据。【方法】采用组织分离法在番茄植株不同部位分离出内生细菌、真菌,结合16SrRNA和ITS序列分析,对候选菌株进行初步鉴定;通过菌株对峙培养、果实离体接种筛选对灰葡萄孢具有拮抗活性的内生菌;进一步测定菌株分泌生长素、嗜铁素的能力及其对拟南芥和番茄幼苗生长的促生特性。【结果】从番茄植株不同部位共分离出72株内生细菌和31株内生真菌,通过平板对峙法筛选出1株对多种病原菌具有较好抑菌活性的内生细菌FQ-G3,分子鉴定为Bacillus velezensis。FQ-G3对灰葡萄孢抑菌率达80.93%,并显著抑制灰葡萄孢在番茄果实上的扩展。该菌株能够分泌生长素、蛋白酶和嗜铁素,且对拟南芥、番茄幼苗具有明显的促生效果。【结论】本研究表明分离自番茄植株的内生菌FQ-G3具...     

Cold tolerance and plant growth promotion potential of Serratia marcescens strain SRM (MTCC 8708) isolated from flowers of summer squash (Cucurbita pepo)

Aim: To determine the cold tolerance and plant growth promotion potential of Serratia marcescens strain SRM (MTCC 8708). Methods and Results: Serratia marcescens strain SRM was isolated from the flowers of summer squash plants, showing no apparent symptoms of yellow vine disease. It was evaluated for growth and plant growth promotion attributes at 15 and 4°C. At 15°C, the isolate was able to solubilize 76·6 μg ml^?1 of P and produce Indole Acetic Acid, IAA (11·1 μg ml^?1). HCN and siderophore production were also detected at 15°C. The isolate retained all the plant growth promotion traits at 4°C. Seed bacterization with the isolate significantly enhanced plant biomass and nutrient uptake of wheat seedlings grown in cold temperatures. Conclusion: Serratia marcescens strain SRM is a promising cold‐tolerant isolate that can significantly influence wheat seedling growth at cold temperatures. Significance and Impact of the Study: This strain can be employed as a bioinoculant in cold temperature conditions.     

小麦赤霉病拮抗菌JB7的拮抗活性及鉴定

由禾谷镰刀菌(Fusarium graminearum, Fg)引起的赤霉病是限制小麦生产的主要病害之一。生物防治是一种高效且可持续的防治方法。【目的】从小麦种子内筛选具有抑制禾谷镰刀菌的菌株并对其生防潜力进行评估,为小麦赤霉病生防制剂的开发与利用提供菌种资源及理论支撑。【方法】采用平板对峙、孢子萌发法和无菌上清液抑菌试验筛选小麦种子内对禾谷镰刀菌具有拮抗活性的内生菌株;利用扫描电镜(scanning electron microscope, SEM)和共聚焦扫描电镜(confocal laser scanning microscope, CLSM)观察并分析无菌上清液对Fg的分生孢子形态、膜完整性以及胞内活性氧的影响;通过盆栽试验验证内生菌对小麦赤霉病的生防效果;应用二代Illumina HiSeq测序平台进行全基因组测序。【结果】从小麦种子中分离出一株高效抑制Fg生长的内生菌株JB7,其衰亡期无菌上清液对Fg孢子萌发抑制率高达85.23%。菌株JB7的无菌上清液使Fg孢子表面凹陷,破坏其细胞膜,造成核酸和蛋白质的渗漏,诱导Fg菌丝活性氧的累积,引起Fg菌丝可溶性蛋白和丙二醛含量的显著升高。该菌株具有分泌蛋白酶、纤维素酶、葡聚糖酶和产铁载体的能力。盆栽试验表明菌株JB7能显著降低小麦赤霉病的病情指数(P<0.05)。经全基因组学鉴定为甲基营养型芽孢杆菌(Bacillus methylotrophicus) JB7,该菌株基因组中含有12个抑菌功能的次级代谢产物合成基因簇。【结论】菌株JB7能抑制禾谷镰刀菌的生长,对小麦赤霉病有较强的防效,可作为生物防治小麦赤霉病的候选菌株。     

Biological control of oilseed rape Sclerotinia stem rot by Bacillus subtilis strain Em7

In the present study, the endophytic bacterium Bacillus subtilis strain Em7 (GU258545.1) was evaluated as a biological control agent for Sclerotinia sclerotiorum on oilseed rape. In petri dish, strain Em7 not only strongly inhibited pathogen mycelium growth but also germination of sclerotia at concentrations between 10⁹ and 10¹¹ colony forming unit (CFU)·ml^?1. Scanning electron microscopy and transmission electron microscopy studies revealed that in the presence of strain Em7, hyphae of S. sclerotiorum showed leakage and disintegration of hyphal cytoplasm. Furthermore, the strain Em7 showed a broad antifungal spectrum on mycelium growth of numerous important plant pathogenic fungi. Light microscopic observations revealed that strain Em7 caused morphological alterations including increased branching, swelling and collapse of cytoplasm. In the greenhouse, spray treatments of cell suspensions of strain Em7 (1×10⁹ CFU·ml^?1) reduced leaf and stem rot incidence and severity in the seedling and blossom stage. The control efficacy was higher when strain Em7 cell suspension was applied one day prior to inoculation of the pathogen than after inoculation. Three-year field trials showed that two applications of strain Em7 cell suspension at blossom stage significantly reduced disease incidence and severity by 50–70%. There was no significant difference in control efficacy among treatments with strain Em7 cell suspension and the fungicides containing carbendazim or tebuconazole (P = 0.05). Thus, our results strongly suggest that B. subtilis strain Em7 is a promising biological control agent for control of oilseed rape Sclerotinia stem rot.     

Increasing <Emphasis Type="Italic">Triticum aestivum</Emphasis> tolerance to cadmium stress through endophytic strains of <Emphasis Type="Italic">Bacillus subtilis</Emphasis>

Impact of inoculation of wheat seeds with endophytic strains of B. subtilis bacterium on revealing cadmium phytotoxicity of the plants was investigated. It was shown that, in the presence of Cd in the plants whose seeds were inoculated with the above bacteria, the activities of catalase and peroxidase and the content of nonprotein thiols were increased, while an intensity of lipid peroxidation decreased. Moreover, inoculation of plant seeds with the bacteria contributed to lowering the metal content in plant shoots.     

Seasonal variation in allelopathic potential of<Emphasis Type="Italic">Artemisia princeps</Emphasis> var.<Emphasis Type="Italic">orientalis</Emphasis> on plants and microbes

We investigated seasonal variations in allelopathic potential ofArtemisia princeps var.orientalis. Aqueous and meth-anol extracts and volatile substances were prepared in the laboratory from samples collected monthly (April through October). Their impacts were then assessed on the germination and seedling growth ofLactuca sativa andAchyranthes japonica. The allelopathic potential varied with the time of sample collection and the concentration tested. For example, germination ofL. sativa was not inhibited by the aqueous extract but seedling growth (shoots and roots) was, with its seasonal effect being significant. ForA. japonica, seed germination was not inhibited at lower concentrations (except for August samples). However, at higher concentrations and in certain months (especially July), germination was more negatively affected. The degree of seedling growth inhibition also differed by month and by extract concentration, with roots being impacted more than shoots. Volatile substances also had a time-dependent influence on the germination and seedling elongation ofA. japonica. In a separate experiment, the ethyl-acetate and water fractions of a crude methanol extract were prepared monthly fromA. princeps var.orientalis. Here, we examined their antimicrobial activities against three gram-positive bacteria (Bacillus cereus, Bacillus subtilis, andStaphylococcus aureus), two gramnegative bacteria (Escherichia coli andPseudomonas fluorescens), and one lactic acid bacterium,Lactobacillus plantar urn. The ethyl-acetate fraction that was sampled in September was remarkably potent againstB. cereus andB. subtilis, whereas the water fraction collected in August and September showed great antimicrobial activity against the grampositive and -negative bacteria. In contrast,L. plantarum was not inhibited by the water fraction, regardless of the sampling month. Likewise, the ethyl-acetate and water fractions collected in April and October had the lowest levels of antimicrobial activity.     

Identification of IAA-producing endophytic bacteria from micropropagated Echinacea plants using 16S rRNA sequencing

The presence of latent bacteria is a serious problem in plant tissue cultures. While endophytes are generally beneficial to plants in situ, they may affect culture growth under the modified conditions in vitro. The present study was undertaken to identify and characterize endophytic bacteria associated with the medicinal plant Echinacea in tissue culture. Based on classical microbiological tests and 16S rRNA analyses, it was found that endophytic bacteria associated with aseptically micropropagated Echinacea plantlets are representatives of several genera, Acinetobacter, Bacillus, Pseudomonas, Wautersia (Ralstonia) and Stenotrophomonas. Based on TLC and HPLC analyses, we found that Pseudomonas stutzeri P3 strain produces plant hormone, auxin (indole-3-acetic acid, IAA). Antibiotic resistance was also assessed as a virulence factor. The majority of endophytic bacteria were resistant to the antibiotic kanamycin, but susceptible to chloramphenicol. Recommendations for propagating Echinacea in vitro cultures involve the addition of chloramphenicol, tetracycline, and ampicillin, antibiotics that cause no side effects on these plant species.     

Biological control of take-all in wheat by endophytic Bacillus subtilis E1R-j and potential mode of action

The bacterial strain E1R-j, isolated as an endophyte from wheat roots, exhibited high antifungal activity to Gaeumannomyces graminis var. tritici (Ggt). Strain E1R-j was identified as Bacillus subtilis based on morphological, physiological and biochemical methods as well as on 16S rDNA analysis. This strain inhibited mycelium growth in vitro of numerous plant pathogenic fungi, especially of Ggt, Coniothyrium diplodiella, Phomopsis sp. and Sclerotinia sclerotiorum. In greenhouse experiments, soil drenches with cell densities of 10⁶, 10⁹ and 10¹² CFU ml⁻¹ E1R-j reduced significantly take-all disease, caused by Ggt, in wheat seedling by 62.6%, 68.6% and 70.7%, respectively, compared to the inoculated control, 4 weeks after sowing. Growth parameters such as lengths and fresh weights of roots and shoots of Ggt-inoculated control plants were significantly lower compared to Ggt-inoculated and E1R-j treated plants. Field experiments in the season 2006/2007, heights of wheat plants in the Ggt inoculated plots were significantly reduced compared to the non inoculated treatments. Yield parameters such as kernels per head and thousand kernel weight (TKW) in inoculated control plants were lower compared to the other treatments. In the experimental year 2007/2008, independent treatments with the bacterial strain E1R-j and the fungicide Triadimefon reduced take-all disease in wheat roots by 55.3% and 61.9%, compared to the inoculated control plants. In this season plant height in inoculated control was significantly lower and also the yield parameters seeds per head and especially TKW were drastically reduced compared to the other treatments. E1R-j treatment alleviated the detrimental effects of take-all on grain yield parameters to a similar extent as Triadimefon application. SEM studies revealed that in the presence of E1R-j, hyphae of Ggt showed leakage, appeared ruptured, swollen and shriveled. Following root drench, strain E1R-j was able to colonize endophytically roots and leaves of wheat seedlings. While the population of the bacterial strain in wheat roots steadily increased from the second to the fourth leaf stage, in the leaf tissue the population of the strain rapidly declined. TEM studies also showed that cells of E1R-j were present in roots of wheat seedlings and effectively retarded infection and colonization of Ggt in root tissue; suppression of Ggt by E1R-j was accompanied by disintegration of hyphal cytoplasm. In addition, in the presence of E1R-j cells in Ggt-infected root tissue morphological defense reactions were triggered such as formation of wall appositions and papillae. The results presented indicate that the endophytic strain E1R-j of B. subtilis meets demands required for biocontrol of take-all.