缓解花生连作障碍的根际促生菌分离及功能鉴定

【目的】长期连作障碍严重降低花生生产的产量及品质,根际促生菌可有效降解土壤中自毒化感物质、抑制植物病原菌生长及促进植物生长,从而有效缓解连作障碍问题。筛选优化具有缓解花生连作障碍能力的多功能根际益生微生物,验证其益生作用能力,为根际促生菌株在连作障碍中的应用提供理论依据及技术支持。【方法】采集连作12年地块花生根际土壤,利用以酚酸为唯一碳源的筛选培养基获得具有酚酸自毒化感物质降解及利用能力的根际促生菌,通过16S rRNA基因测序进行系统发育分析,确定根际促生菌菌株的分类地位,并验证其对植物病原菌生长抑制能力及解磷、解钾、产植物激素吲哚乙酸能力。【结果】从连作12年的花生发病土壤中获得7株可高效降解酚酸类自毒物质且降解底物多样的根际微生物菌株,经16S rRNA测序比对分别为克雷伯氏菌B02 (Klebsiella sp. B02)、克雷伯氏菌B07(Klebsiella sp. B07)、克雷伯氏菌B15 (Klebsiella sp. B15)、芽孢杆菌B28 (Bacillus sp. B28)、不动杆菌P09(Acinetobacter sp. P09)、布鲁氏杆菌VA05 (...     

岑溪药用野生稻高效内生固氮菌分离及促生特性

【目的】以广西岑溪市野生稻保护区的药用野生稻为材料,分离纯化内生细菌,筛选固氮酶活性较高和对作物促生效果较好的菌株。【方法】利用乙炔还原法检测固氮酶活性,采用SDS-PAGE全细胞蛋白电泳和IS-PCR指纹图谱技术对分离到的固氮菌进行聚类。利用16S rRNA基因和nifH基因确定其系统发育地位。采用钼锑抗比色法、Salkowski比色法和CAS检测法分别测定菌株溶磷性、生长素的分泌能力和产铁载体能力。通过平板和盆栽试验检测其对水稻的促生作用。【结果】共分离得到35株内生固氮菌,分为6个类群。其中CX24固氮酶活性最高,经鉴定属于Klebsiella variicola,其固氮酶活性为298.64 μmol/(L·h),为参比模式菌株DSM15968的9倍。另外该菌株还具有较高的溶磷性、分泌生长素和产铁载体能力,能够有效地促进水稻的萌发和生长。【结论】菌株CX24属于Klebsiella variicola,是一株高效内生固氮菌,具有很好的生产应用前景。     

落地生根内生固氮菌多样性和促生特性

【背景】内生固氮菌可以定殖于植物体内为植物提供营养物质,还能通过代谢促进植物生长,目前对于落地生根内生菌的研究鲜见报道。【目的】研究落地生根中内生固氮菌多样性。【方法】从表面消毒的植物组织中分离纯化内生菌,并通过乙炔还原法测定菌株的固氮酶活性。采用SDS-PAGE全细胞蛋白电泳和IS指纹图谱对菌株聚类,各类群代表菌株进行16S rRNA基因系统发育分析和生理生化鉴定。测定菌株固氮、分泌生长素和ACC脱氨酶、产铁载体、溶磷和解钾等促生特性。【结果】从落地生根中分离纯化出26株内生固氮菌,聚为5个类群,隶属于4个属的5个菌种,且各类群代表菌株具有多种促生功能。【结论】从落地生根中分离获得的内生菌具有丰富的遗传多样性和促生特性,并且存在新的微生物资源,有待开发利用。     

水稻内生固氮菌Herbaspirillum seropedicae DX35的筛选及其促生特性

摘要:【目的】筛选水稻高效内生固氮菌,并对其促生特性进行分析。【方法】从湖南祁阳中国农业科学院红壤实验站具30年长期稻-稻-绿肥轮作定位试验田中采集水稻根并分离内生细菌,通过乙炔还原法测定其固氮酶活性,筛选出固氮活性较高的菌株,运用16S rRNA基因、nifH基因以及脂肪酸分析确定其发育地位。同时采用Salkowski比色法测定其生长素的分泌能力,CAS蓝色平板检测法测定产铁载体能力,溶磷圈法测定溶磷性,对其促生特性进行分析。【结果】共分离获得48株内生菌,其中DX35固氮酶活性最高,经鉴定属于Herbaspirillum seropedicae,其固氮酶活性为181.21 nmol C2H4/(mg protein·h),约是参比菌株Azotobacter chroococcum ACCC10006的10倍。另外该菌株还具有一定的分泌铁载体能力和溶磷特性。【结论】DX35属于H.seropedicae,是一种高效内生固氮菌,具有很好的生产应用前景。     

水稻内生固氮菌Herbaspirillum seropedicae DX35的筛选及其促生特性

【目的】筛选水稻高效内生固氮菌,并对其促生特性进行分析。【方法】从湖南祁阳中国农业科学院红壤实验站具30年长期稻-稻-绿肥轮作定位试验田中采集水稻根并分离内生细菌,通过乙炔还原法测定其固氮酶活性,筛选出固氮活性较高的菌株,运用16S rRNA基因、nifH基因以及脂肪酸分析确定其发育地位。同时采用Salkowski比色法测定其生长素的分泌能力,CAS蓝色平板检测法测定产铁载体能力,溶磷圈法测定溶磷性,对其促生特性进行分析。【结果】共分离获得48株内生菌,其中DX35固氮酶活性最高,经鉴定属于Herbaspirillum seropedicae,其固氮酶活性为181.21 nmol C2H4/(mg protein·h),约是参比菌株Azotobacter chroococcum ACCC10006的10倍。另外该菌株还具有一定的分泌铁载体能力和溶磷特性。【结论】DX35属于H.seropedicae,是一种高效内生固氮菌,具有很好的生产应用前景。     

广西甘蔗根际高效联合固氮菌的筛选及鉴定

对广西主要甘蔗产区的根际联合固氮细菌进行了收集和评价,拟筛选获得对甘蔗具有潜在促生性能的联合固氮菌,为甘蔗生产节肥减耗提供依据。结合nifH基因扩增和固氮酶活性分析方法筛选获得36个固氮细菌菌株;进一步对所获得固氮菌株的固氮能力、溶磷性、分泌植物生长素IAA的特性等促进植物生长潜能进行评价,获得了5个同时具有较强固氮能力、降解无机磷和分泌植物生长激素IAA的功能菌株;通过Biolog鉴定系统和16S rRNA序列分析对5个具有较好应用潜力的固氮菌进行分类鉴定。结果表明这5个菌株分别属于Klebsiella sp.、Bacillus megaterium、Pseudomonas sp.、Pantoea sp.和Burkholderia sp.。本研究结果表明广西甘蔗根际联合固氮菌具有较大的开发利用潜力。     

4株茶树根际促生菌菌株的鉴定及促生作用

【背景】根际促生菌可以促进植物生长、提高植物抗性。茶树根际具有特殊的根土微生物生境,可以获得具促生作用的有益微生物。【目的】探究4株茶树根际促生菌菌株的分类地位及促生作用,筛选优良的根际促生菌菌株。【方法】通过形态、生理生化特征、16S rRNA基因序列同源性比对鉴定4株茶树根际促生菌,采用钼锑抗比色法测定溶磷量,通过比色法测定ACC脱氨酶活性、CAS法测定产铁载体能力、Salkowski法测定产IAA (Indoleacetic acid)的能力进行促生作用研究,通过盆栽实验测试白菜、空心菜、苋菜及水稻的株高及鲜重以分析促生效应。【结果】鉴定KKS-6-N1为放射型土壤杆菌(Agrobacteriumradiobacter), KKS-7-N7为铜绿假单胞菌(Pseudomonas aeruginosa),GD3为Pseudomonashunanensis,GD12为弯曲芽孢杆菌(Bacillusflexus)。固氮菌株KKS-6-N1可产铁载体;固氮菌株KKS-7-N7具有解磷及产铁载体能力,分泌的IAA含量高达101.29mg/L;解钾菌株GD3具溶磷能力,分泌的ACC脱氨酶酶活为8.09μmol/(mg·h),相对铁载体含量为0.31;具固氮解钾性能的菌株GD12分泌的ACC脱氨酶活性为14.46μmol/(mg·h)。盆栽试验表明,4个菌株对白菜、空心菜、苋菜的株高和鲜重均有明显促进作用,尤以GD3效果更甚。【结论】茶树根际促生菌菌株Pseudomonas hunanensis GD3促生作用显著,具有开发成微生物菌肥的潜力。     

鄱阳湖-乐安河段湿地耐Cu、Zn、Pb植物促生菌的分离、筛选及鉴定

【背景】植物促生菌因其对植物生长促进及增强抗逆性等优点在植物-微生物联合修复重金属污染土壤中具有良好应用潜力。在污染土壤中,土著植物促生菌能够更好地定殖并保证促植物生长能力的发挥。【目的】从常年受上游多种重金属污染的鄱阳湖-乐安河段湿地分离出一批具有多种重金属抗性的优势土著植物促生菌,以期为植物-微生物联合修复重金属污染湿地提供一批优质的菌种资源。【方法】从乐安河流域戴村受重金属污染的湿地土壤及水体中分离具有Cu、Zn、Pb抗性菌株,测定菌株的促植物生长特性[产IAA(Indole acetic acid)、溶磷、产铁载体及ACC(1-Aminocyclopropane-1-carboxylic acid)脱氨酶活性],挑选促生特性较好的菌株进行16S r RNA基因序列分析鉴定,并测定菌株对其他胁迫条件(抗生素、酸碱、盐)的耐受能力。【结果】分离得到22株能够同时耐受Cu 50 mg/L、Zn 400 mg/L、Pb 800 mg/L的菌株,其中10株表现出较好的促植物生长特性,对其进行16S r RNA基因序列分析鉴定,有4株属于Ralstonia sp.,3株属于Burkholderia sp.,另3株则分别属于Cupriavidus sp.、Stenotrophomonas sp.和Novosphingobium sp.。基于这10株菌抗性特征的聚类分析及主成分分析,结果与系统发育树分析结果高度一致。【结论】耐受多种重金属的土著植物促生菌的分离鉴定为重金属污染土壤的植物-微生物联合原位修复提供良好的微生物资源。     

广西葛根内生细菌的分离鉴定及其促生特性

【背景】植物内生菌长期与宿主共生,对宿主生长发育产生影响。葛根作为重要的药食两用作物,葛根内生菌的研究具有重要实践意义。【目的】对广西葛根根部内生细菌进行分离、鉴定及促植物生长特性分析,旨在了解该药食同源植物内生细菌种群结构及其促生特性,为分析内生菌群体在药食同源植物产量和品质形成的作用及其内生细菌资源的开发利用提供参考。【方法】采用6种不同的培养基从广西葛根的根瘤、根系和根愈伤组织分离内生细菌,16S rRNA基因测序和系统发育分析内生细菌的分布特征和遗传多样性,采用生理生化方法测定分离菌株的固氮活性、溶磷特性、产生嗜铁素、分泌吲哚乙酸(indole-3-aceticacid,IAA)等促生特性。【结果】从葛根根瘤、根系和根部愈伤组织中共分离得到223个菌株,16S rRNA基因测序鉴定这些菌株隶属于2门4纲10科19属,其中芽孢杆菌属、假单胞菌属、土壤杆菌属、肠杆菌属为葛根优势菌群;内生细菌数量和群落组成存在明显的组织特异性,其数量表现为根瘤>根系>根愈伤组织,但其种群多样性表现为根愈伤组织>根系>根瘤。不同培养基分离出的细菌种群丰富度有差异。从供试菌株中筛...     

如东田菁根瘤菌遗传多样性及高效促生菌株筛选

摘要:【目的】研究江苏如东沿海滩涂田菁根瘤菌的遗传多样性和系统发育,筛选高效促生田菁根瘤菌。【方法】采用16S rRNA基因、持家基因(recA、atpD、glnⅡ)、共生基因(nodA、nifH)的系统发育分析,并进行温室盆栽接种试验筛选高效菌株。【结果】分离到的32株田菁根瘤菌分布于Ensifer、Neorhizobium、Rhizobium,并与E. meliloti、N. huautlense、E. sesbaniae、R. pusense 亲缘关系最近。共生基因nodA、nifH的系统进化分析结果基本一致,均与E. saheli 最为相近。7株代表菌株均能耐受5%的NaCl(W/V)浓度,其中YIC5082耐盐性最强,能够耐受6%的NaCl。温室盆栽试验表明7 株代表菌株均能与田菁有效结瘤固氮,其中6株菌显著提高了植株的株高和鲜重。【结论】江苏如东沿海滩涂田菁根瘤菌具有较丰富的遗传多样性,其中N．huautlense、E．meliloti为优势种。该地区的田菁根瘤菌多数具有较好的共生有效性及耐盐性,YIC5077促生效果最为突出,并表现出较强的固氮及结瘤能力,具有良好的应用前景。     

植物根际促生菌促生特性研究进展

根际微生物组是决定农作物健康状况的关键因素之一,也是调节农作物与生物和非生物环境相互作用的重要因素。植物根际促生菌(plant growth-promoting rhizobacteria, PGPR)为农作物宿主提供了多种有益作用,通过化学交流以复杂的方式与农作物、土壤相互作用,进而促进农作物生长。本文综述了PGPR对农作物的促生机制、PGPR与农作物的互作及其在农业实践中的应用,并展望了PGPR在农业实践中应用的发展趋势,以期为今后PGPR的应用和研究提供新的思路和理论支撑。     

Plant perceptions of plant growth-promoting Pseudomonas

Plant-associated Pseudomonas live as saprophytes and parasites on plant surfaces and inside plant tissues. Many plant-associated Pseudomonas promote plant growth by suppressing pathogenic micro-organisms, synthesizing growth-stimulating plant hormones and promoting increased plant disease resistance. Others inhibit plant growth and cause disease symptoms ranging from rot and necrosis through to developmental dystrophies such as galls. It is not easy to draw a clear distinction between pathogenic and plant growth-promoting Pseudomonas. They colonize the same ecological niches and possess similar mechanisms for plant colonization. Pathogenic, saprophytic and plant growth-promoting strains are often found within the same species, and the incidence and severity of Pseudomonas diseases are affected by environmental factors and host-specific interactions. Plants are faced with the challenge of how to recognize and exclude pathogens that pose a genuine threat, while tolerating more benign organisms. This review examines Pseudomonas from a plant perspective, focusing in particular on the question of how plants perceive and are affected by saprophytic and plant growth-promoting Pseudomonas (PGPP), in contrast to their interactions with plant pathogenic Pseudomonas. A better understanding of the molecular basis of plant-PGPP interactions and of the key differences between pathogens and PGPP will enable researchers to make more informed decisions in designing integrated disease-control strategies and in selecting, modifying and using PGPP for plant growth promotion, bioremediation and biocontrol.     

Applications of free living plant growth-promoting rhizobacteria

Free-living plant growth-promoting rhizobacteria (PGPR) can be used in a variety of ways when plant growth enhancements are required. The most intensively researched use of PGPR has been in agriculture and horticulture. Several PGPR formulations are currently available as commercial products for agricultural production. Recently developing areas of PGPR usage include forest regeneration and phytoremediation of contaminated soils. As the mechanisms of plant growth promotion by these bacteria are unravelled, the possibility of more efficient plant-bacteria pairings for novel and practical uses will follow. The progress to date in using PGPR in a variety of applications with different plants is summarized and discussed here.     

植物根际促生菌的筛选及鉴定

【目的】植物根际促生菌(PGPR)和植物的互作关系往往不稳定,PGPR菌群有可能提高菌株对野外环境的适应性。为此,本文根据PGPR促生机制的多样性,从不同植物根际土壤进行了PGPR的筛选及鉴定。【方法】首先,按照固氮、解磷、解钾、拮抗6种常见病原真菌,同时能在植物根际定殖为基本初筛标准,然后在实验室条件下测定初筛菌株的多项促生能力(PGP),最后通过生理生化试验和16SrRNA基因序列分析对所筛菌株进行鉴定。【结果】从江苏扬州、盐城等地土壤样品筛选出14株PGPR,具有体外抑菌、产NH3、产IAA、产HCN、产嗜铁素、解磷、溶钾、固氮以及产抗生素等促生能力。分类鉴定结果显示:7株属于假单胞菌属(Pseudomonas)、3株属于类芽孢杆菌属(Paenibacillus)、2株为芽孢杆菌属(Bacillus)、1株为布克霍尔德氏菌属(Burkholderia)、1株为欧文氏菌属(Erwinia)。【结论】所筛细菌具有多种促生能力,且能在根际定殖,为进一步构建多功能PGPR广适菌群提供菌株资源。     

Use of plant growth-promoting rhizobacteria to control stress responses of plant roots

Ethylene is a key gaseous hormone that controls various physiological processes in plants including growth, senescence, fruit ripening, and responses to abiotic and biotic stresses. In spite of some of these positive effects, the gas usually inhibits plant growth. While chemical fertilizers help plants grow better by providing soil-limited nutrients such as nitrogen and phosphate, over-usage often results in growth inhibition by soil contamination and subsequent stress responses in plants. Therefore, controlling ethylene production in plants becomes one of the attractive challenges to increase crop yields. Some soil bacteria among plant growth-promoting rhizobacteria (PGPRs) can stimulate plant growth even under stressful conditions by reducing ethylene levels in plants, hence the term “stress controllers” for these bacteria. Thus, manipulation of relevant genes or gene products might not only help clear polluted soil of contaminants but contribute to elevating the crop productivity. In this article, the beneficial soil bacteria and the mechanisms of reduced ethylene production in plants by stress controllers are discussed.     

Hydrocarbon utilization by nodule bacteria and plant growth-promoting rhizobacteria

Standard and locally isolated nodule bacteria and plant growth-promoting rhizobacteria (PGPR) were grown on crude oil and individual pure hydrocarbons as sole sources of carbon and energy. The nodule bacteria included two standard Rhizobium leguminosarum strains, two standard Bradyrhizobium japonicum strains, and one unknown nodule bacterial strain that was locally isolated from Vicia faba nodules. The PGPR included one standard Serratia liquefaciens strain and two locally isolated strains of Pseudomonas aeruginosa and Flavobacterium sp. The pure hydrocarbons tested included n-alkanes with chain lengths from C9 to C40 and the aromatic hydrocarbons benzene, biphenyle, naphthalene, phenanthrene, and toluene. Quantitative gas liquid chromatographic analyses confirmed that pure cultures of representative nodule bacteria and PGPR could attenuate n-octadecane and phenanthrene in the surrounding nutrient medium. Further, intact nodules of V. faba containing bacteria immobilized on and within those nodules reduced hydrocarbon levels in a medium in which those nodules were shaken. It was concluded that legume crops are suitable phytoremediation tools for oily soil, since they enrich such soils not only with fixed nitrogen, but also with hydrocarbon-utilizing microorganisms. Further, legume nodules may have biotechnological value as materials for cleaning oily liquid wastes.     

Rock phosphate-solubilizing Actinomycetes: screening for plant growth-promoting activities

In order to select Actinobacteria that could improve plant growth and thus agricultural yield, we assessed different plant growth promoting (PGP) abilities of eight rock phosphate (RP)-solubilizing Actinomycete isolates originating from Moroccan phosphate mines. Six of these strains were able to grow on root exudates of the wheat plant as sole nutrient sources and were efficiently releasing soluble phosphate from RP. These strains also inhibited the growth of potentially phytopathogenic fungi, bacteria (Gram +/−) or yeasts. Five of these strains produced indoleacetic acid and four showed endophytic properties. When these strains were grown, in the presence of the wheat plant, in a synthetic minimum medium (SMM) containing insoluble RP as unique phosphate source or in soil experiment, the most active RP-solubilizing strains had the highest stimulatory effect on the production of plant biomass. The most efficient strain Streptomyces griseus-related strain (BH₇), stimulated aerial growth of the plant more than 70% in test tubes and more than 30% in RP soil compared to the non-inoculated control treatment. This study demonstrated that our selected Actinomycete strains could be used for the development of novel, non-polluting; farming practices by entering in the formulation of novel biofertilizer and biocontrol products constituted by spores and/or mycelium of the ad hoc Actinobacteria in association with pulverized RP.     

Inoculants of plant growth-promoting bacteria for use in agriculture

An assessment of the current state of bacterial inoculants for contemporary agriculture in developed and developing countries is critically evaluated from the point of view of their actual status and future use. Special emphasis is given to two new concepts of inoculation, as yet unavailable commercially: (i) synthetic inoculants under development for plant-growth-promoting bacteria (PGPB) (Bashan and Holguin, 1998), and (ii) inoculation by groups of associated bacteria.This review contains: A brief historical overview of bacterial inoculants; the rationale for plant inoculation with emphasis on developing countries and semiarid agriculture, and the concept and application of mixed inoculant; discussion of microbial formulation including optimization of carrier-compound characteristics, types of existing carriers for inoculants, traditional formulations, future trends in formulations using unconventional materials, encapsulated synthetic formulations, macro and micro formulations of alginate, encapsulation of beneficial bacteria using other materials, regulation and contamination of commercial inoculants, and examples of modern commercial bacterial inoculants; and a consideration of time constraints and application methods for bacterial inoculants, commercial production, marketing, and the prospects of inoculants in modern agriculture.     

Genetic diversity of cultivable plant growth-promoting rhizobacteria in Korea

To elucidate the biodiversity of plant growth-promoting rhizobacteria (PGPR) in Korea, 7,638 bacteria isolated from the rhizosphere of plant species growing in many different regions were screened. A large number of PGPR were identified by testing the ability of each isolate to promote the growth of cucumber seedlings. After redundant rhizobacteria were removed via amplified rDNA restriction analysis, 90 strains were finally selected as PGPR. On the basis of 16S ribosomal RNA sequences, 68 Gram-positive (76%) and 22 Gram-negative (24%) isolates were assigned to 21 genera and 47 species. Of these genera, Bacillus (32 species) made up the largest complement, followed by Paenibacillus (19) and Pseudomonas (11). Phylogenetic analysis showed that most of the Grampositive PGPR fell into two categories: low- and high- G+C (Actinobacteria) strains. The Gram-negative PGPR were distributed in three categories: alpha-proteobacteria, beta- proteobacteria, and gamma-proteobacteria. To our knowledge, this is the largest screening study designed to isolate diverse PGPR. The enlarged understanding of PGPR genetic diversity provided herein will expand the knowledge base regarding beneficial plant-microbe interactions. The outcome of this research may have a practical effect on crop production methodologies.