基因标记枯草芽孢杆菌BS-68A在黄瓜上定殖

目的:野生型枯草芽孢杆菌Bacillus subtilisBS-68能有效地防治由Pythium spp.和Fusarium oxporum引起的黄瓜立枯病和枯萎病。为了探究该菌株的生防机制,利用该菌株的黄绿荧光蛋白基因和氯霉素抗性基因标记菌株BS-68A研究其在黄瓜植株各个部位的定殖能力、种群动态和在根围的分布。方法和结果:用基因标记菌株发酵液分别对黄瓜种子进行浸种和浇穴处理,播种后30d,该菌能在黄瓜根部和茎基部定殖,不能在茎部和叶部定殖。浸种处理,该菌在茎基部的种群数量为3.1×104cfu/株,大于根部的种群数量4.1×102cfu/株;浇穴处理,该菌在茎基部的种群数量8.0×103cfu/株,低于根部的种群数量2.5×104cfu/株。     

多功能菌群混合施用的生态效应

从蔬菜地黄瓜根围土壤中经分离筛选,得到两个对黄瓜枯萎病菌(Fusarium oxysporum f.sp.cucumerinum)有抑制作用,并能明显促进黄瓜生长的菌株ZJY-1(Brevibacillus brevis)和ZJY-116(Bacillus subtilis).将这两菌株与一株毒死蜱降解菌DSP3(Alcaligenes faecali)按照不同组合处理黄瓜种子,以研究多功能菌群在环境中发挥生态效应的可行性.结果表明,这两株具有生防和促生功能的菌株与DSP3按不同组合混合后,对黄瓜的防病促生作用均不受影响.同时对黄瓜根围土中毒死蜱含量检测分析发现,DSP3与这两株细菌混和施用后其降解率与单独施用相比没有明显差异.实验初步证明,不同功能的菌株混合施用后可以发挥其生态效应.     

枯草芽孢杆菌ZH-8对黄瓜霜霉病防治效果的研究

枯草芽孢杆菌ZH-8分离于黄瓜根际,将该菌株发酵后,添加助剂制成液体菌剂。该液体菌剂在温室试验和田间试验中表现出较好的防治效果,对黄瓜霜霉病的防效分别达75．61％和69．12％。该菌剂可以有效抑制黄瓜霜霉病菌孢子囊的萌发,并且能够在黄瓜叶片上形成一层保护膜,阻止病原菌孢子的侵入。同时对其抗利福平标记菌株进行了在黄瓜叶片上定殖的研究,研究表明,该生防菌株在黄瓜叶片上具有较强的定殖能力,定殖时间达21d。     

内生枯草芽孢杆菌JL4在葡萄叶上的定殖及其对葡萄霜霉病的防治

为了明确枯草芽孢杆菌JL4在葡萄叶表面和内部的定殖情况,研究定殖与防治效果的关系,采用电击转化的方法将含有GFP基因的质粒pGFP78导入枯草芽孢杆菌JL4中,并得到成功表达GFP 的生防菌JL4-gfp,测试了标记菌株的稳定性及其对葡萄霜霉病菌的抑制作用.采用叶片喷雾法接种,用抗生素平板稀释分离回收,检测生防菌JL4-gfp在葡萄叶片的定殖情况,并将采回的叶片在室内接种葡萄霜霉菌孢子囊悬浮液进行生防测定.结果表明: 标记菌株在经过10次传代培养后,仍具有良好的发光表型,能稳定表达GFP蛋白,并且标记菌株JL4-gfp对葡萄霜霉菌保持了原有的抑菌作用;用抗生素平板稀释分离回收,检测到JL4-gfp菌株在葡萄叶片表面的定殖量在接种后的0、3和7 d分别为3.6×10⁵、2.7×10⁵和3.1×10³ CFU·g^-1;叶片内部的定殖在接种3 d后达到最大(9.6×10⁴ CFU·g^-1),然后下降,14 d后已经检测不到接种菌株;室内生防测定结果显示,喷雾后3 d对葡萄霜霉病的防治效果达88.0%以上,但7 d后则无明显防效.JL4-gfp的定殖量与其防治葡萄霜霉病的效果呈正相关,其有效定殖量临界值为10⁵ CFU·g^-1.     

蜡样芽孢杆菌B3-7在大田小麦根部的定殖动态及其对小麦纹枯病的防治效果

为了阐明蜡样芽孢杆菌B3-7在大田条件下的生态适应性以及对于小麦纹枯病的生防效果,通过利用绿色荧光蛋白编码基因gfp标记生防菌株B3-7,室内比较了GFP标记菌株和原始出发菌株在菌落形态、生长特性,生物薄膜产生以及在小麦根部定殖等方面的特性,结果发现GFP标记菌株和出发菌株在上述特性方面无明显差别。在此基础上,大田条件下测定了GFP标记菌株在小麦根部的定殖动态和对于小麦纹枯病的生防效果。结果发现,GFP标记菌株在小麦根部能够长期定殖,其存在量在小麦分蘖期最大,每克根重达到105CFU,拔节期后,该细菌数量一直维持在104CFU之上。同时发现,生防菌株能够有效降低小麦纹枯病的严重度和提高罹病小麦的产量。小麦分蘖期、孕穗期和灌浆期生防菌对于小麦纹枯病的防治效果分别达到60%、34%,34%,小麦成熟后产量提高13%—15%。结果表明,B3-7在大田条件下具有较好的生态适应性和防治小麦纹枯病的能力。     

海洋细菌L_1-9双抗菌株的定殖能力及其对黄瓜枯萎病的防治作用

采用抗生素标记法,对海洋多黏类芽孢杆菌L1-9菌株进行标记,抗性菌株L1-9Str,rif对链霉素和利福平的抗性浓度分别为160μg/m L和20μg/m L。双抗菌株L1-9Str,rif的抑菌特性及其对链霉素和利福平的抗性经多次传代仍比较稳定。盆栽试验表明,该双抗菌株能在黄瓜根部土壤及根组织、茎基部、子叶和真叶组织中定殖。菌株L1-9Str,rif在黄瓜外根际、根际和根表土壤及黄瓜组织中的定殖动态基本一致,初期黄瓜组织中L1-9Str,rif菌量较少,随着时间的延长,菌量逐渐增加,达到高峰后逐渐减少。菌株L1-9Str,rif在根表土壤中菌量最多(1.76×109 CFU/g),其次是根际土壤,外根际土壤中菌量较少;在黄瓜组织中,菌株L1-9Str,rif其在子叶中的定殖能力最强(5.63×104 CFU/g),其次是根和茎基部(0-2 cm);调查至第26 d时在根部土壤中的含菌量仍保持在稳定的水平,其中根表土壤中含菌量最高(2.41×107 CFU/g),在黄瓜组织样品中,子叶中的含菌量最高(4.15×104 CFU/g);温室防病实验结果表明,菌株L1-9和L1-9Str,rif菌株对黄瓜枯萎病具有良好的防治效果,不同时期防效均达70%以上。上述结果表明来自海洋的多黏类芽孢杆菌L1-9菌株能在黄瓜根部土壤及幼苗组织中定殖,是一株有潜力的黄瓜枯萎病生防菌株。     

辣椒内生细菌BS-1和BS-2在植物体内的定殖及鉴定

以抗利福平为标记,用浸种、涂叶和灌根方法接种,测定菌株在植物体内的定殖。结果表明,来自辣椒体内的BS_2和BS_1菌株不仅可在辣椒体内定殖,也可在番茄、茄子、黄瓜、甜瓜、西瓜、丝瓜、小白菜等植物体内定殖,BS_2菌株还可在水稻、小麦及豇豆等植物体内定殖,BS_2菌株的内生定殖宿主范围比BS_1菌株的广;另外BS_2菌株可在辣椒和白菜体内较长期定殖。用常规方法、Biolog及16S rRNA序列比较,两菌株鉴定为枯草芽杆菌内生亚种（Bacillus subtilis subsp. endophyticus）。     

生防放线菌Ahn75的荧光标记及其在水稻中的定殖

【背景】目前gfp标记基因已成为研究靶标微生物与宿主之间互作的一种重要工具。利用gfp基因标记生防菌株,可以对生防菌株的生存及定殖能力进行有效追踪。【目的】对生防放线菌Ahn75进行荧光标记,探讨其在水稻中的定殖规律,为研究Ahn75的稻瘟病防治机制奠定基础。【方法】首先通过电激转化将含绿色荧光标记基因(gfp)的质粒pIJ8655导入大肠杆菌ET12567中,然后采用接合转移的方法将gfp整合到Ahn75基因组上;通过平板对峙试验检验Ahn75-GFP在标记绿色荧光后对稻瘟病病原菌的抑菌活性;采用喷施孢子液的方式将带荧光标记的Ahn75-GFP定殖水稻,并利用荧光显微镜观察生防菌在水稻中的定殖情况;对定殖水稻中的内生菌进行重分离,探究菌株在水稻组织中的分布规律。【结果】PCR扩增和荧光观察表明,绿色荧光标记基因成功整合到生防放线菌Ahn75中。通过平板对峙试验,发现Ahn75-GFP对稻瘟病病原菌抑菌活性与原始菌株没有显著差别。在荧光显微镜下,可以观察到Ahn75-GFP能稳定定殖于水稻的根、茎、叶等组织中,而水稻内生菌重分离试验表明该菌株在茎中的定殖力最强。【结论】获得一株绿色荧光标记生防菌株Ahn75-GFP,结果显示该菌株定殖水稻效果良好,这对于研究Ahn75的稻瘟病防治具有重要意义。     

类芽孢杆菌QHZ11-gfp在马铃薯植株上的定殖特征及促生效果

[背景] 生防菌在作物根系的有效定殖是其功能发挥的前提,而直观的跟踪技术和有效的定量方法是研究生防菌根系分布规律的重要工具。[目的] 研究马铃薯黑痣病病原菌立枯丝核菌（Rhizo ctonia solani） JT18的拮抗菌QHZ11在马铃薯植株上的定殖特征及对马铃薯的促生效果。[方法] 采用绿色荧光蛋白（Green Fluorescent Protein,GFP）对QHZ11进行标记,将标记菌株菌悬液、生物有机肥和无菌水分别接种至灭菌土壤,通过激光共聚焦显微技术和实时荧光定量PCR等方法观察和测定标记菌株在马铃薯植株不同部位的定殖特征、数量变化及对马铃薯的促生效果。[结果] pHAPII质粒成功导入QHZ11并可稳定遗传40代,记为QHZ11-gfp;菌株标记前后的菌落形态、生长曲线和对R.solani JT18的拮抗能力等基本一致。从第7天开始,相继在马铃薯芽上和根上发现了绿色荧光,说明QHZ11-gfp成功定殖到了马铃薯的芽、根等部位。QHZ11-gfp在根系和匍匐茎的定殖数量均呈现先升高至块茎形成期达到峰值后下降的趋势,并且在整个生育期根系的定殖数量始终大于匍匐茎。菌悬液和生物有机肥处理均显著促进了马铃薯根系的生长,并通过增加株高等农艺性状提高了块茎产量。其中,生物有机肥处理在各部位的荧光强度、定殖数量和对马铃薯的促生效果均显著优于菌悬液。[结论] QHZ11-gfp可在马铃薯植株上成功定殖并对马铃薯有良好的促生效果,将其制成生物有机肥促进了其定殖,使促生效果也更好。     

含绿色荧光蛋白标记的木霉表达载体的构建

ACCC 30150是由本实验室筛选的一株对黄瓜枯萎病、青椒疫病等多种土传病害具有较好防治效果的长柄木霉生防菌,为研究其在蔬菜根际的定殖情况,本试验将含绿色荧光蛋白(GFP)和潮霉素B抗性的融合基因交换整合到真核表达骨架载体pNOM102上.通过酶切鉴定和测序鉴定证明目的片段与载体片段连接正确,木霉表达载体pNOM102-HygEGFP构建成功,为下一步进行生防木霉根际定殖研究奠定基础.     

硅酸盐细菌NBT菌株在小麦根际定殖的初步研究

对硅酸盐细菌NBT菌株进行了耐药性标记,得到稳定的链霉素抗性标记菌NBT菌株,采用选择性培养基分离计数,通过琼脂平板和盆栽试验,研究了标记菌NBT在小麦根际的定殖动态及影响因素。结果表明,在灭菌土盆栽中,播种后9d左右NBT菌株在小麦根际的定殖水平达最高(1．4×10^8cfu·g^-1根土),播种后54d左右趋向稳定,NBT菌株细胞数量为2．4×10^3cfu·g^-1根土;未灭菌土盆栽中,播种后9d左右NBT菌株的定殖水平达最高(3．8×10^8cfu·g^-1根土),60d左右趋向稳定,菌数为3．1×10^3cfu·g^-1根土,牛物和非牛物因素对NBT菌株定殖小麦根系有影响。     

Rhizosphere Colonization and Control of Meloidogyne spp. by Nematode-trapping Fungi

The ability of nematode-trapping fungi to colonize the rhizosphere of crop plants has been suggested to be an important factor in biological control of root-infecting nematodes. In this study, rhizosphere colonization was evaluated for 38 isolates of nematode-trapping fungi representing 11 species. In an initial screen, Arthrobotrys dactyloides, A. superba, and Monacrosporium ellipsosporum were most frequently detected in the tomato rhizosphere. In subsequent pot experiments these fungi and the non-root colonizing M. geophyropagum were introduced to soil in a sodium alginate matrix, and further tested both for establishment in the tomato rhizosphere and suppression of root-knot nematodes. The knob-forming M. ellipsosporum showed a high capacity to colonize the rhizosphere both in the initial screen and the pot experiments, with more than twice as many fungal propagules in the rhizosphere as in the root-free soil. However, neither this fungus nor the other nematode-trapping fungi tested reduced nematode damage to tomato plants.     

消除共生质粒的费氏中华根瘤菌HND29SR在大豆根圈的定殖动态

比较研究了费氏中华根瘤菌（Sinorhizobium fredii)HN01(出发菌）、发光酶基因标记菌HNO1L（参照菌）、消除HN01共生质粒的菌株HND29SR在无菌砂培条件下的大豆根圈定殖动态。供试菌单独接种时：HN01、HN01L和HND29SR的定殖动态基本一致,其早期定殖密度下降较快,播种后第16天时HN01和HN01L分别达到较高的定殖水平6.49logcfu/g鲜根和6.78logcfu/g鲜根,然后维持相对稳定的定殖水平。但HND29SR的定殖密度持续下降到播种后第16天时才开始上升,至第35天时仍维持相对稳定的定殖密度6.94logcfu/g鲜根。等量混合接种时供试菌在根圈定殖群体中各自定殖密度在测定过程中基本相等。结果表明消除HN01的共生质粒对其在大豆根圈中定殖能力无显著影响。     

Colonization of peanut roots by biofilm-forming Paenibacillus polymyxa initiates biocontrol against crown rot disease

Aim: To investigate the role of biofilm‐forming Paenibacillus polymyxa strains in controlling crown root rot disease. Methods and Results: Two plant growth‐promoting P. polymyxa strains were isolated from the peanut rhizosphere, from Aspergillus niger‐suppressive soils. The strains were tested, under greenhouse and field conditions for inhibition of the crown root rot pathogen of the peanut, as well as for biofilm formation in the peanut rhizosphere. The strains’ colonization and biofilm formation were further studied on roots of the model plant Arabidopsis thaliana and with solid surface assays. Their crown root rot inhibition performance was studied in field and pot experiments. The strains’ ability to form biofilms in gnotobiotic and soil systems was studied employing scanning electron microscope. Conclusion: Both strains were able to suppress the pathogen but the superior biofilm former offers significantly better protection against crown rot. Significance and Impact of the Study: The study highlights the importance of efficient rhizosphere colonization and biofilm formation in biocontrol.     

Survival of gfp-tagged antagonistic bacteria in the rhizosphere of tomato plants and their effects on the indigenous bacterial community

The survival and colonization patterns of Pseudomonas putida PRD16 and Enterobacter cowanii PRF116 in the rhizosphere of greenhouse-grown tomato plants and the effects of their inoculation on the indigenous bacterial community were followed by selective plating, molecular fingerprinting, and confocal laser scanning microscopy (CLSM) over 3 weeks. Both strains, which showed in vitro antagonistic activity against Ralstonia solanacearum, were previously tagged with gfp. Seed and root inoculation were compared. Although plate counts decreased for both gfp-tagged antagonists, PRD16 showed a better survival in the rhizosphere of tomato roots independent of the inoculation method. Analysis of 16S rRNA gene fragments amplified from total community DNA by denaturing gradient gel electrophoresis and CLSM confirmed the decrease in the relative abundance of the inoculant strains. Pronounced differences in the Pseudomonas community patterns for plants inoculated with PRD16 compared to the control were detected 3 weeks after root inoculation, indicating a longer-lasting effect. Analysis by CLSM showed rather heterogeneous colonization patterns for both inoculant strains. In comparison with seed inoculation, root inoculation led to a much better colonization as evidenced by all three methods. The colonization patterns observed by CLSM provide important information on the sampling strategy required for monitoring inoculant strains in the rhizosphere.     

Cotton roots and vitamin-requiring and amino acid-requiring bacteria

Summary The rhizosphere effects of diploid and amphidiploid strains of cotton in black cotton soils have been investigated with reference to vitamin-requiring bacteria and amino acid-requiring bacteria. Influence of cotton roots on amino acid-requiring bacteria was found to be greater than on vitamin-requiring bacteria. The rhizosphere effects of diploid strains were greater than those of amphidiploid strains. The effects were also influenced by the initial proportions of these bacterial groups in the two soils. The rhizosphere effects of inoculated plants were lower than the respective healthy controls; but those of apparently healthy (disease escapes) diploid plants and those of inoculated amphidiploid plants in PLD soil (wilt-sick) were strikingly higher than the healthy controls. Differences in the rhizosphere effects between diploid and amphidiploid plants could be correlated with the amino acid and vitamin exudations by roots of these strains, but not with reference to soil types.Part of Doctoral Thesis, University of Madras.     

Relationship between root colonization and initial adsorption ofAzospirillum to plant roots

Four strains ofAzospirillum were ranked according to numbers of cells adsorbed on the roots of seedlings in liquid medium, and the rankings were evaluated for their usefulness in predicting success of colonization of the roots of pot-grown plants. Different rankings were observed on different parts of the roots and on different host plants. Rhizosphere colonization results for rice were similar to those for clover and showed little difference between bacterial strains. The population densities were approximately equal to those of the most dense strains in the wheat rhizosphere, whereas the highest concentrations in the root interior of clover and rice were only about one-tenth of those in wheat. Rankings of initial adsorptive ability on various parts of the roots showed potential for predicting the best strains for colonizing the root interiors of wheat and clover. On wheat, the two strains (Cd and SpBr14) which showed best initial adsorption to the root cap were best at colonizing the endorhizosphere of pot-grown plants. For rice, strains Cd and SpBr14 gave lowest and highest values, respectively, both for adsorption to the terminal 2 cm of roots and for subsequent colonization of the root interior. Data on initial adsorption were of no value in predicting the relative success of strains in colonizing the root surface of any host plants or the interior of clover roots.     

Colonization of the developing rhizosphere of sugar beet seedlings by potential biocontrol agents applied as seed treatments

AIMS: Poor colonization of the rhizosphere is a major constraint of seed treatment biological control. The objectives of this study were to; examine the colonization of the rhizosphere of sugar beet seedlings by selected rhizobacteria; determine the influence of the host rhizosphere and percolating water on the distribution of the bacteria; and deliver two biological control agents (BCAs) by co-inoculation. METHODS AND RESULTS: Rifampicin-resistant bacterial strains (Rif +) applied as single treatments to seed sown in columns of field soil produced persistent populations of 5-9 log10 cfu g-1 in the infection court of the damping-off pathogen Aphanomyces cochlioides in a controlled environment. However, isolates varied in their ability to colonize the lower rhizosphere. Percolating water significantly increased the colonization of the upper rhizosphere. Bacterial populations in the soil profiles of "non-rhizosphere" controls declined markedly with time. There was no interaction between the two selected BCAs applied as a seed treatment mixture. CONCLUSIONS: The distribution of the bacteria resulted primarily from root colonization although percolating water may modify the colonization profiles. Co-inoculation of the sugar-beet rhizosphere is a viable proposition. SIGNIFICANCE AND IMAPCT OF THE STUDY: Potential BCAs were successfully delivered to the known infection court of A. cochloides and persisted for the infection period. This bioassay can be used as a tool for the selection of BCAs for field trials.     

Synergistic effects of biofilm-producing PGPR strains on wheat plant colonization,growth and soil resilience under drought stress

Drought stress substantially impedes crop productivity throughout the world. Microbial based approaches have been considered a potential possibility and are under study. Based on our prior screening examination, two distinct and novel biofilm-forming PGPR strains namely Bacillus subtilis-FAB1 and Pseudomonas azotoformans-FAP3 are encompassed in this research. Bacterial biofilm development on glass surface, microtiter plate and seedling roots were assessed and characterized quantitatively and qualitatively by light and scanning electron microscopy. Above two isolates were further evaluated for their consistent performance by inoculating on wheat plants in a pot-soil system under water stresses. Bacterial moderate tolerance to ten-day drought was recorded on the application of individual strains with wheat plants; however, the FAB1 + FAP3 consortium expressively improved wheat survival during drought. The strains FAB1 and FAP3 displayed distinct and multifunctional plant growth stimulating attributes as well as effective roots and rhizosphere colonization in combination which could provide sustained wheat growth during drought. FAB1 and FAP3-induced alterations cooperatively conferred improved plant drought tolerance by controlling physiological traits (gs, Ci, E, iWUE and P_N), stress indicators (SOD, CAT, GR, proline and MDA content) and also maintained physico-chemical attributes and hydrolytic enzymes including DHA, urease, ALP, protease, ACP and β glucosidase in the soil. Our findings could support future efforts to enhance plant drought tolerance by engineering the rhizobacterial biofilms and associated attributes which requires in-depth exploration and exploiting potential native strains for local agricultural application.