Agricultural Soil Bacteria; A Study of Collection, Cultivation, and Lysogeny

Sides, Katherine Elizabeth

01 May 2010

The aim of this research project was to test new collection and cultivation techniques that may increase the range of cultivable diversity of soil bacteria. Fortified BioSep beads were employed in situ to capture soil bacteria, and the success of the beads was analyzed using Phylochip microarray analysis. In the cultivation phase, three different media substrates and increased incubation period were evaluated for the ability to select novel or rare bacteria. Over 700 agricultural soil bacterial isolates were classified, including a rare Gemmatimonadetes sp., a rare Verrucomicrobia sp., several Acidobacteria sp., and many novel isolates. Land management, media, and incubation period each resulted in lineage specific preferences. The yeast fortified BioSep bead cultivation collection was significantly different from the bulk soil or acyl homoserine lactone (AHL) fortified bead cultivation collections, and there were lineage specific differences in all three collection types. Phylochip analysis showed a significant difference between bulk soil and all BioSep bead (water, yeast, or AHL fortified) communities based on microarray analysis of 16S rDNA. The yeast fortified BioSep bead community was richer in operational taxonomic units (OTU) than all others. The number of phyla determined by the Phylochip analysis was much higher than that seen in the overall cultivation collection. Prophage induction assays of 21 isolates were performed, using mitomycin C (mitC) and a mixture of six AHLs, to examine soil lysogenic phage-host interactions. The fraction induced by mitC was 29%, and 10% were induced by AHL. There was no correlation between induction and land management or host growth rate. This research showed that increases in cultivable diversity can be attained by the use of BioSep beads in the collection process, varying media substrates, and by extending incubation of inoculate cultures. Phylochip analysis, however, revealed that even with altered cultivation methods, there is still a wealth of soil bacterial diversity that remains to be cultivated from this site. We also found that AHLs impact the interactions between soil bacterial hosts and prophage.

Soil bacteria

BioSep Beads

Cultivation

Phylochip

Lysogenic

Agricultural Soil Bacteria; A Study of Collection, Cultivation, and Lysogeny

Sides, Katherine Elizabeth

01 May 2010

The aim of this research project was to test new collection and cultivation techniques that may increase the range of cultivable diversity of soil bacteria. Fortified BioSep beads were employed in situ to capture soil bacteria, and the success of the beads was analyzed using Phylochip microarray analysis. In the cultivation phase, three different media substrates and increased incubation period were evaluated for the ability to select novel or rare bacteria. Over 700 agricultural soil bacterial isolates were classified, including a rare Gemmatimonadetes sp., a rare Verrucomicrobia sp., several Acidobacteria sp., and many novel isolates. Land management, media, and incubation period each resulted in lineage specific preferences. The yeast fortified BioSep bead cultivation collection was significantly different from the bulk soil or acyl homoserine lactone (AHL) fortified bead cultivation collections, and there were lineage specific differences in all three collection types. Phylochip analysis showed a significant difference between bulk soil and all BioSep bead (water, yeast, or AHL fortified) communities based on microarray analysis of 16S rDNA. The yeast fortified BioSep bead community was richer in operational taxonomic units (OTU) than all others. The number of phyla determined by the Phylochip analysis was much higher than that seen in the overall cultivation collection.Prophage induction assays of 21 isolates were performed, using mitomycin C (mitC) and a mixture of six AHLs, to examine soil lysogenic phage-host interactions. The fraction induced by mitC was 29%, and 10% were induced by AHL. There was no correlation between induction and land management or host growth rate. This research showed that increases in cultivable diversity can be attained by the use of BioSep beads in the collection process, varying media substrates, and by extending incubation of inoculate cultures. Phylochip analysis, however, revealed that even with altered cultivation methods, there is still a wealth of soil bacterial diversity that remains to be cultivated from this site. We also found that AHLs impact the interactions between soil bacterial hosts and prophage.

Soil bacteria

BioSep Beads

Cultivation

Phylochip

Lysogenic

Nutzung molekularer Hochdurchsatz-Verfahren zur schnellen und eingehenden Artenbestimmung von Pilzgesellschaften / Using high-throughput genotyping for monitoring communities of soil fungi

Reich, Marlis

28 May 2009

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

Pilze

Phylochip

Arraytechnik

454 Pyrosequenzierung

Artenvielfalt Pilzgesellschaften

Waldbaumarten

fungi

phylochip

array technique

454 pyrosequencing

mycorrhizal community structure

host preference

tree species

42

W

Influence of root exudates on soil microbial diversity and activity

Shi, Shengjing

January 2009

Interactions between plant roots and soil microorganisms in the rhizosphere are critical for plant growth. However, understanding of precisely how root exudates influence the diversity and activity of rhizosphere microorganisms is limited. The main objective of this study was to investigate the effect of radiata pine (Pinus radiata) root exudates on rhizosphere soil microbial communities, with an emphasis on the role of low molecular weight organic anions. The study involved the development and validation of new methods for investigating rhizosphere processes in a purpose-built facility. This included development of an in situ sampling technique using an anion exchange membrane strip to collect a range of organic anions exuded from radiata pine roots grown in large-scale rhizotrons. These included tartarate, quinate, formate, malate, malonate, shikimate, lactate, acetate, maleate, citrate, succinate and fumarate. Soil microbial activity and diversity were determined using dehydrogenase activity and denaturing gradient gel electrophoresis. Links between organic anions in root exudates and rhizosphere soil microbial community structures were investigated by comparing wild type and genetically modified radiata pine trees which were grown in rhizotrons for 10 months. As expected, there was considerable temporal and spatial variability in the amounts and composition of organic anions collected, and there were no consistent or significant differences determined between the two tree lines. Significant differences in rhizosphere microbial communities were detected between wild type and genetically modified pine trees; however, they were inconsistent throughout the experiment. The shifts in microbial communities could have been related to changes in exudate production and composition. Based on results from the main rhizotron experiment, a microcosm study was carried out to investigate the influence of selected pine root exudate sugars (glucose, sucrose and fructose) and organic anions (quinate, lactate and maleate) on soil microbial activity and diversity. Soil microbial activity increased up to 3-fold in all of the sugar and organic anion treatments compared to the control, except for a mixture of sugars and maleate where it decreased. The corresponding impacts on soil microbial diversity were assessed using denaturing gradient gel electrophoresis and 16S rRNA phylochips. Addition of the exudate compounds had a dramatic impact on the composition and diversity of the soil microbial community. A large number of bacterial taxa (88 to 1043) responded positively to the presence of exudate compounds, although some taxa (12 to 24) responded negatively. Organic anions had a greater impact on microbial communities than sugars, which indicated that they may have important roles in rhizosphere ecology of radiata pine. In addition, a diverse range of potentially beneficial bacterial taxa were detected in soil amended with organic anions, indicating specific regulation of rhizosphere microbial communities by root exudates. This project highlighted the considerable challenges and difficulties involved in detailed investigation of in situ rhizosphere processes. Nonetheless, the findings of this study represent a significant contribution to advancing understanding of relationships between root exudates and soil microbial diversity, which will be further enhanced by refinement and application of the specific methodologies and techniques developed.

rhizosphere

root exudates

organic anions

soil microbial community

diversity

in situ

anion exchange membrane

radiata pine (Pinus radiata)

genetically modified

rhizotron

rRNA

DGGE

phylochip