应用16S rDNA克隆文库法分析有机物料腐熟菌剂细菌组成

应用16SrDNA克隆文库法对有机物料腐熟菌剂A和B样品中的细菌组成进行分析研究。结果表明,样品A有14个OTU,主要是融合乳杆菌(Weissella confusa)、枯草芽孢杆菌(Bacillus subtilis)和短小芽孢杆菌(Bacillus pumilus),其比例分别占总克隆文库的28.6%、30.4%和23.2%;样品B有43个OTU,主要是布氏乳杆菌(Lactobacillus buchneri)、香肠乳杆菌(Lactobacillus farciminis)和耐酸乳杆菌(Lactobacillus acetotolerans),占总克隆文库的比例分别为18.03%、18.86%和13.12%;所得出的结果均与产品标注存在差异,样品A未提及细菌的种类,而样品B只标注短小芽孢杆菌。研究表明这一方法在微生物菌剂细菌组成分析及其质量检测中具有良好的应用前景。     

AM真菌种间差异对枳壳生长及耐热性效应的研究※

用地表球囊霉、莫西球囊霉、珠状巨孢球囊霉及其混合菌剂接种无菌根枳壳幼苗进行盆栽试验,25℃培养4个月,观察对枳壳菌根形成和营养生长的影响,在40℃高温胁迫30d,调查分析菌根枳壳的耐热性。试验结果表明:接种AM真菌的根系形成了20%～80%的菌根侵染率;菌根枳壳的苗高、苗质量、节间长、茎基粗、须根数量和须根长度等营养生长显著增加;叶片中的SOD,POD活性和根系活力显著增强,可溶性蛋白、可溶性糖含量显著升高,叶片中的MDA含量降低,膜透性显著变小,枳壳苗的耐热性显著提高;但是,AM真菌在促进枳壳苗菌根化、营养生长和提高耐热性方面存在着种间差异,地表球囊霉、莫西球囊霉、珠状巨孢球囊霉、混合菌剂与枳壳根系形成丛枝菌根的侵染率依次为20.4%±1.2%、61.8%±3.4%、85.7%±2.7%、83.3%±2.2%,促进枳壳苗营养生长提高枳壳苗耐热能力的AM真菌依次为:地表球囊霉<莫西球囊霉<珠状巨孢球囊霉<混合菌剂,认为珠状巨孢球囊霉和莫西球囊霉是枳壳耐高温胁迫菌根化育苗的重要优良菌种。     

Survival, root colonisation and biocontrol capacities of Pseudomonas fluorescens F113 LacZY in dry alginate microbeads

Cells of Pseudomonas fluorescens F113 LacZY were encapsulated in alginate and their survival and ability to colonise sugar beet were evaluated. To assess survival, the formulation, composed of dry alginate microbeads of 300- to 700-μm diameter, was stored 1 year at 28±2 and 4±2°C and then tested against pathogenic fungi Pythium ultimum and Rhizoctonia solani in in vitro inhibition experiments. The same material was also used as inoculant for protection of sugar beet against Py. ultimum in microcosm experiments. The results obtained indicated that, although drying alginate beads resulted in a significant reduction of bacterial viability, the use of microbeads enabled a satisfactory level of root colonisation and protection, at least under microcosm conditions. The capability of the encapsulated cells to produce the antifungal metabolite 2,4-diacetylphloroglucinol (Phl) was not significantly affected by 12 months storage. Journal of Industrial Microbiology & Biotechnology (2001) 27, 337–342. Received 07 September 2000/ Accepted in revised form 08 May 2001     

Can commercial soil microbial treatments remediate plant–soil feedbacks to improve restoration seedling performance?

Seedling performance is often a limiting factor in ecological restoration. Changes in the soil microbial community generated by invasive plants contribute to seedling failure. A method to remediate invasive species‐induced changes to the soil microbial community that results in increased native species seedling performance and decreased invasive species seedling performance could have a large impact on the success of many restoration efforts. In a greenhouse experiment, we first examined the changes in the soil microbial community created by invasive compared to native grasses. Then, we investigated four microbial treatments (bacterial inoculant, fungal inoculant, fungicide, and bactericide/fungicide) to remediate microbial plant–soil feedbacks (PSFs) created by invasive species Bromus inermis and Poa pratensis and increase the performance of natives Andropogon gerardii, Elymus canadensis, Pascopyrum smithii, and Schizachyrium scoparium. We found that the PSF mitigation treatments had some context‐dependent utility for restoration. For example, all of the treatments decreased the performance of B. inermis and fungal inoculant decreased the performance of P. pratensis. However, no single treatment increased the performance of all natives. Fungicide increased the performance of A. gerardii and E. canadensis in soil previously occupied by B. inermis and the performance of S. scoparium in soil previously occupied by P. pratensis. If validated in the field, PSF mitigation treatments may have utility for restoration practitioners.     

Seed coating with beneficial microorganisms for precision agriculture

Seed coating is a technique of covering seeds with adhesive agents to improve seed performance and plant establishment while reducing production cost. To meet the needs of development of precision agriculture, seed coating has been widely used in agriculture as an effective means to alleviate biotic and abiotic stresses, thus enhancing crop growth, yield, and health. Plant growth promoting microorganisms (PGPM) are recognized as essential contributors to improving agricultural productivity via direct application to the rhizosphere and plant tissues, or seed inoculation. However, during conventional inoculation processes, several factors such as insufficient microbial survival, hindrance in the application of biocontrol inocula to the seeds and exposure to unsuitable temperature and light in subsequent seed storage, force us to explore efficient and reliable microbial application tools. Recently, biological seed coating with PGPM is proposed as an alternative to conventional seed treatment (such as fertilizer and protection products) due to its ecological safety and socio-economic aspects. In this review, microbial seed coating technology and its contribution to sustainable precision agriculture are well discussed and highlighted in the extensive table and elaborate schematic drawings.     

Natural variation of Macrocystis pyrifera gametophyte germplasm culture microbiomes and applications for improving yield in offshore farms

With national interest in seaweed-based biofuels as a sustainable alternative to fossil fuels, there is a need for tools that produce high-yield seaweed cultivars and increase the efficiency of offshore farms. Several agricultural studies have demonstrated that the application of microbial inoculants at an early life stage can improve crop yield, and there is an opportunity to use similar techniques in seaweed aquaculture. However, there is a critical knowledge gap regarding host–microbiome associations of macroalgae gametophytes in germplasm cultures. Here, we investigate the microbial community of Macrocystis pyrifera gametophyte germplasm cultures that were used to cultivate an offshore farm in Santa Barbara, California and identify key taxa correlated with increased biomass of mature sporophytes. This work provides a valuable knowledge base for the development of microbial inoculants that produce high-biomass M. pyrifera cultivars to ultimately be used as biofuel feedstocks.