Biogeochemical Cycling and Microbial Communities in Native Grasslands:Responses to Climate Change and Defoliation

Attaeian, Behnaz

Unknown Date

No description available.

Climate Change

Carbon Cycling

Nitrogen Cycling

Soil Microbial Community

Grassland

Greenhouse Gas Emissions

Warming

Precipitation

Defoliation

Global Warming

Potrebbe l'applicazione di pesticidi influenzare l'abbondanza, la struttura, la biodiversità e la funzionalità della comunità microbica del suolo? / COULD PESTICIDE APPLICATION AFFECT ABUNDANCE, STRUCTURE, BIODIVERSITY AND FUNCTIONALITY OF SOIL MICROBIAL COMMUNITY?

PERTILE, GIORGIA

17 March 2016

In agricoltura, i pesticidi sono stati usati molto frequentemente per salvaguardare le colture dagli attacchi di parassiti e dalle malattie. Questi pesticidi, oltre a uccidere gli organismi target, molte volte colpiscono anche gli organismi non-target. Tra gli organismi non-target, possiamo individuare molti microrganismi utili a determinare la fertilità e la qualità del terreno. La presenza di questi xenobiotici nel terreno può influenzare i principali cicli biogeochimici (N, C, S, P) e altre vie metaboliche (es. β-ketoadipate). In questo studio abbiamo analizzato gli effetti di isoproturon, tebuconazole e chlorpyrifos sull’abbondanza, sulla struttura e sulla diversità della comunità microbica. Inoltre, abbiamo anche studiato gli effetti di questi pesticidi sui geni coinvolti nel ciclo dell’azoto. Si è potuto notare che l’abbondanza della comunità batterica è molto influenzata dall’applicazione del fungicida tebuconazole . Per quanto riguarda gli studi sulla funzionalità e diversità della popolazione microbica, l’applicazione di questi pesticidi sembra non indurre una chiara dose-dipendente e un effetto tempo. Diversamente, in relazione all’analisi sulla diversità microbica, possiamo affermare che l’applicazione di questi tre pesticidi ha influenzato il numero di OTU rilevate; tuttavia, l’indice di diversità (H’) ci dice che l’uso di questi pesticidi porta ad un incremento della diversità all’interno dei campioni trattati. In conclusione, è possibile affermare che l’applicazione di questi pesticidi influenza l’abbondanza e la funzionalità della popolazione microbica, ma non induce una diminuzione della diversità all’interno della medesima comunità. / In agriculture, pesticides have been frequently used to protect crops from pest and disease attacks. Many times such pesticides, besides killing the target organisms, hit non-target organisms. Among the non-target organisms, we can find many useful microorganisms that determine fertility and soil quality. The presence of these xenobiotics in soil can influence the main biogeochemical cycles (N, C, S, P) and other metabolic pathways (eg. Β-ketoadipate). In this study, we investigated the effects of isoproturon, tebuconazole and chlorpyrifos on the abundance, the structure and the diversity of the microbial community. We have also studied the effects of these pesticides on the genes involved in the nitrogen cycle. It was observed that the abundance of the bacterial community is significantly affected by the application of the fungicide tebuconazole. As for the studies on the functionality and the diversity of the bacterial population, the application of these pesticides does not seem to induce a clear dose-dependent nor a time effect. On the contrary, with respect to the analysis on microbial diversity, we observed that the application of these three pesticides did influence the number of detected OTU, whereas the diversity index (H') tells us that the use of such pesticides leads to an increase of diversity within the treated samples. Finally, we can conclude that the application of these pesticides affects the abundance and function of the microbial population, but does not lead to lower diversity within the same community.

AGR/16: MICROBIOLOGIA AGRARIA

BIO/11: BIOLOGIA MOLECOLARE

AGR/13: CHIMICA AGRARIA

MANAGING SOIL MICROBIAL COMMUNITIES WITH ORGANIC AMENDMENTS TO PROMOTE SOIL AGGREGATE FORMATION AND PLANT HEALTH

Lucas, Shawn T.

01 January 2013

The effects of managing soil with organic amendments were examined with respect to soil microbial community dynamics, macroaggregate formation, and plant physio-genetic responses. The objective was to examine the possibility of managing soil microbial communities via soil management, such that the microbial community would provide agronomic benefits. In part one of this research, effects of three amendments (hairy vetch residue, manure, compost) on soil chemical and microbial properties were examined relative to formation of large macroaggregates in three different soils. Vetch and manure promoted fungal proliferation (measured via two biomarkers: fatty acid methyl ester 18:2ω6c and ergosterol) and also stimulated the greatest macroaggregate formation. In part two of this research, effects of soil management (same amendments as above, inorganic N fertilization, organic production) on soil chemical and microbial properties were examined relative to the expression of nitrogen assimilation and defense response genes in tomato (Solanum lycopersicum L.). Soil management affected expression of a nitrogen assimilation gene (GS1, glutamine synthetase) and several defense-related genes. The GS1 gene was downregulated with inorganic N fertilization, expression of the pathogenesis-related PR1b gene (which codes for the pathogenesis-related PR1b protein) was increased in plants grown in soil amended with compost, vetch, and N fertilizer, and expression of three other defense-related genes coding for chitinase (ChiB), osmotin (Osm), and β-1,3-glucanase (GluA) were decreased in plants from soil amended with manure and in plants from the organically managed soil. Differential expression of defense-related genes was inversely related to the relative abundance of Gram-negative bacteria. The relative abundance of the 18:1ω7c Gram‑negative bacterial biomarker was greatest in manure treated soil and in organically managed soil (which recieves seasonal manure applications). These treatments also had the lowest expression of ChiB, Osm, and GluA, leading to speculation that manure, through increases in Gram-negative bacteria, may have suppressed populations of soil organisms that induce a defense response in plants, possibly allowing for less-stressed plants. Outcomes of this research may be useful for those interested in developing management strategies for maintaining or improving soil structure as well as those interested in understanding management effects plant physio-genetic responses.

Soil management

Organic amendments

Soil microbial community

Soil structure

Plant gene expression

Agricultural Science

Agronomy and Crop Sciences

Biodiversity

Soil Science

Sustainability

The effect of pulse crops on arbuscula mycorrhizal fungi in a durum-based cropping system

Fraser, Tandra

07 April 2008

Pulses are an important component in crop rotations in the semiarid Brown soil zone of southern Saskatchewan, Canada. Besides their capability to fix nitrogen, pulse crops establish a strong symbiotic relationship with arbuscular mycorrhizal fungi (AMF), which have been shown to increase nutrient and water uptake through hyphal extensions in the soil. Incorporating strongly mycorrhizal crops in a rotation may increase inoculum levels in the soil and benefit the growth of a subsequent crop. The objective of this study was to determine if AMF potential and colonization of a durum crop is significantly affected by cropping history and to assess the impact of pulses in crop rotations on the abundance and diversity of AMF communities in the soil. In 2004 and 2005, soil, plant, and root samples were taken on Triticum turgidum L. (durum) with preceding crops of Pisum sativum L. (pea), Lens culinaris Medik (lentil), Cicer arietinum L. (chickpea), Brassica napus L. (canola) or Triticum turgidum L. (durum). Although there were few differences in soil N and P levels, previous crop had a significant effect (p<0.05) on durum yields in both years. A previous crop of pea was associated with the highest yields, while the durum monocultures were lowest. Arbuscular mycorrhizal potential and colonization were significantly affected (p<0.05) by cropping history, but not consistently as a result of inclusion of a pulse crop. Phospholipid and neutralipid fatty acids (PLFA/NLFA) were completed to analyse the relative abundance of AMF (C16:1ù5), saprophytic fungi (C18:2ù6), and bacteria in the soil. The effect of treatment on the abundance of AMF, saprotrophic fungi and bacteria were not significant (p<0.05), but the changes over time were. These results demonstrate that although previous crop may play a role in microbial community structure, it is not the only influencing factor.

Soil Microbial Community Structure

Pulse Crops

Crop Rotation

Arbuscular Mycorrhizal Fungi

Durum Wheat

Pea

Lentil

Canola

Phospholipid Fatty Acid Profile

Water Use Efficiency

The effect of pulse crops on arbuscula mycorrhizal fungi in a durum-based cropping system

Fraser, Tandra

07 April 2008

Pulses are an important component in crop rotations in the semiarid Brown soil zone of southern Saskatchewan, Canada. Besides their capability to fix nitrogen, pulse crops establish a strong symbiotic relationship with arbuscular mycorrhizal fungi (AMF), which have been shown to increase nutrient and water uptake through hyphal extensions in the soil. Incorporating strongly mycorrhizal crops in a rotation may increase inoculum levels in the soil and benefit the growth of a subsequent crop. The objective of this study was to determine if AMF potential and colonization of a durum crop is significantly affected by cropping history and to assess the impact of pulses in crop rotations on the abundance and diversity of AMF communities in the soil. In 2004 and 2005, soil, plant, and root samples were taken on Triticum turgidum L. (durum) with preceding crops of Pisum sativum L. (pea), Lens culinaris Medik (lentil), Cicer arietinum L. (chickpea), Brassica napus L. (canola) or Triticum turgidum L. (durum). Although there were few differences in soil N and P levels, previous crop had a significant effect (p<0.05) on durum yields in both years. A previous crop of pea was associated with the highest yields, while the durum monocultures were lowest. Arbuscular mycorrhizal potential and colonization were significantly affected (p<0.05) by cropping history, but not consistently as a result of inclusion of a pulse crop. Phospholipid and neutralipid fatty acids (PLFA/NLFA) were completed to analyse the relative abundance of AMF (C16:1ù5), saprophytic fungi (C18:2ù6), and bacteria in the soil. The effect of treatment on the abundance of AMF, saprotrophic fungi and bacteria were not significant (p<0.05), but the changes over time were. These results demonstrate that although previous crop may play a role in microbial community structure, it is not the only influencing factor.

Soil Microbial Community Structure

Pulse Crops

Crop Rotation

Arbuscular Mycorrhizal Fungi

Durum Wheat

Pea

Lentil

Canola

Phospholipid Fatty Acid Profile

Water Use Efficiency

Exotic earthworms and soil microbial community composition in a northern hardwood forest

Dempsey, Mark Austin.

January 2009

Title from first page of PDF document. Includes bibliographical references (p. 22-27).

Soilborne disease suppressiveness / conduciveness : analysis of microbial community dynamics / by Johannes Hendrikus Habig

Habig, Johannes Hendrikus

January 2003

Take-all is the name given to the disease caused by a soilborne fungus Gaeumannomyces graminis (Sacc.) von Arx and Olivier var. tritici Walker (Ggt), an ascomycete of the family Magnaportheaceae (Cook, 2003). This fungus is an aggressive soil-borne pathogen causing root rot of wheat (primary host), barley and rye crops (secondary host). The flowering, seedling, and vegetative growth stages can be affected by the infection of the whole plant, leaves, roots, and stems. Infections of roots result in losses in crop yield and quality primarily due to a lowering in nutrient uptake. Take-all is most common in regions where wheat is cultivated without adequate crop rotation. Crop rotation allows time between the planting dates of susceptible crops, which causes a decrease in the inoculum potential of soilborne plant pathogens to levels below an economic threshold by resident antagonistic soil microbial communities. Soilborne disease suppressiveness is an inherent characteristic of the physical, chemical, and/or biological structure of a particular soil which might be induced by agricultural practices and activities such as the cultivation of crops, or the addition of organisms or nutritional amendments, causing a change in the microfloral environment. Disturbances of soil ecosystems that impact on the normal functioning of microbial communities are potentially detrimental to soil formation, energy transfers, nutrient cycling, and long-term stability. In this regard, an overview of soil properties and processes indicated that the use of microbiological and biochemical soil properties, such as microbial biomass, the analysis of microbial functional diversity and microbial structural diversity by the quantification of community level physiological profiles and signature lipid biomarkers are useful as indicators of soil ecological stress or restoration properties because they are more responsive to small changes than physical and chemical characteristics. In this study, the relationship between physico-chemical characteristics, and different biological indicators of soil quality of agricultural soils conducive, suppressive, and neutral with respect to take-all disease of wheat as caused by the soilborne fungus Gaeumannomyces graminis var. tritici (Ggt), were investigated using various techniques. The effect of crop rotation on the functional and structural diversity of soils conducive to take-all disease was also investigated. Through the integration of quantitative and qualitative biological data as well as the physico-chemical characteristics of the various soils, the functional and structural diversity of microbial IV communities in the soils during different stadia of take-all disease of wheat were characterised. All results were evaluated statistically and the predominant physical and chemical characteristics that influenced the microbiological and biochemical properties of the agricultural soils during different stadia of take-all disease of wheat were identified using multivariate analyses. Although no significant difference @ > 0.05) could be observed between the various soils using conventional microbiological enumeration techniques, the incidence of Gliocladium spp. in suppressive soils was increased. Significant differences @ < 0.05) were observed between agricultural soils during different stadia of take-all disease of wheat. Although no clear distinction could be made between soils suppressive and neutral to take-all disease of wheat, soils suppressive and conducive to take-all disease of wheat differed substantially in their community level physiological profiles (CLPPs). Soils suppressive / neutral to take-all disease were characterised by enhanced utilisation of carboxylic acids, amino acids, and carbohydrates, while conducive soils were characterised by enhanced utilisation of carbohydrates. Shifts in the functional diversity of the associated microbial communities were possibly caused by the presence of Ggt and associated antagonistic fungal and bacterial populations in the various soils. It was evident that the relationships amongst the functionality of the microbial communities within the various soils had undergone changes through the different stages of development of take-all disease of wheat, thus implying different substrate utilisation capabilities of present soil microbial communities. Diversity indices were calculated as Shannon's diversity index (H') and substrate equitability (J) and were overall within the higher diversity range of 3.6 and 0.8, respectively, indicating the achievement of very high substrate diversity values in the various soils. A substantial percentage of the carbon sources were utilised, which contributed to the very high Shannon-Weaver substrate utilisation indices. Obtained substrate evenness (equitability) (J) indices indicated an existing high functional diversity. The functional diversity as observed during crop rotation, differed significantly (p < 0.05) from each other, implying different substrate utilisation capabilities of present soil microbial communities, which could possibly be ascribed to the excretion of root exudates by sunflowers and soybeans. Using the Sorenson's index, a clear distinction could be made between the degrees of substrate utilisation between microbial populations in soils conducive, suppressive, and neutral to take-all disease of wheat, as well as during crop rotation. Furthermore, the various soils could also be differentiated on the basis of the microbial community structure as determined by phospholipid fatty acid (PLFA) analysis. Soil suppressive to take-all disease of wheat differed significantly (p < 0.05) from soils conducive, and neutral to take-all disease of wheat, implying a shift in relationships amongst the structural diversity of microbial communities within the various soils. A positive association was observed between the microbial phospholipid fatty acid profiles, and dominant environmental variables of soils conducive, suppressive, and neutral to take-all disease of wheat. Soils conducive and neutral to take-all disease of wheat were characterised by high concentrations of manganese, as well as elevated concentrations of monounsaturated fatty acids, terminally branched saturated fatty acids, and polyunsaturated fatty acids which were indicative of Gram-negative bacteria, Gram-positive bacteria and micro eukaryotes (primarily fungi), respectively. These soils were also characterised by low concentrations of phosphorous, potassium, percentage organic carbon, and percentage organic nitrogen, as well as low soil pH. Soil suppressive to take-all disease of wheat was characterised by the elevated levels of estimated of biomass and elevated concentrations of normal saturated fatty acids, which is ubiquitous to micro-organisms. The concentration of normal saturated fatty acids in suppressive soils is indicative of a low structural diversity. This soil was also characterised by high concentrations of phosphorous, potassium, percentage organic carbon, and percentage organic nitrogen, as well as elevated soil pH. The relationship between PLFAs and agricultural soils was investigated using principal component analysis (PCA), redundancy analysis (RDA) and discriminant analysis (DA). Soil suppressive to take-all disease of wheat differed significantly (p < 0.05) from soils conducive, and neutral to take-all disease of wheat, implying a shift in relationships amongst the structural diversity of microbial communities within the various soils. A positive association was observed between the microbial phospholipid fatty acid profiles, and dominant environmental variables of soils conducive, suppressive, and neutral to take-all disease of wheat. Hierarchical cluster analysis of the major phospholipid fatty acid groups indicated that the structural diversity differed significantly between soils conducive, suppressive, and neutral to take-all disease of wheat caused by Gaeumannomyces graminis var. tritici. The results indicate that the microbial community functionality as well as the microbial community structure was significantly influenced by the presence of take-all disease of wheat caused by Gaeumannomyces graminis var. tritici, and that the characterisation of microbial functional and structural diversity by analysis of community level physiological profiles and phospholipid fatty acid analysis, respectively, could be successfully used as an assessment criteria for the evaluation of agricultural soils conducive, suppressive, and neutral to take-all disease of wheat, as well as in crop rotation systems. This methodology might be of significant value in assisting in the management and evaluation of agricultural soils subject to the prevalence of other soilborne diseases. / Thesis (M.Sc. (Microbiology))--North-West University, Potchefstroom Campus, 2004.

Soil microbial communities

Gaeumannomyces graminis var. tritici

Take-all disease

Crop rotation

Diversity indices

Soil microbial community structure

Phospholipid fatty acids (PFLAs)

Soilborne disease suppressiveness / conduciveness : analysis of microbial community dynamics / by Johannes Hendrikus Habig

Habig, Johannes Hendrikus

January 2003

Take-all is the name given to the disease caused by a soilborne fungus Gaeumannomyces graminis (Sacc.) von Arx and Olivier var. tritici Walker (Ggt), an ascomycete of the family Magnaportheaceae (Cook, 2003). This fungus is an aggressive soil-borne pathogen causing root rot of wheat (primary host), barley and rye crops (secondary host). The flowering, seedling, and vegetative growth stages can be affected by the infection of the whole plant, leaves, roots, and stems. Infections of roots result in losses in crop yield and quality primarily due to a lowering in nutrient uptake. Take-all is most common in regions where wheat is cultivated without adequate crop rotation. Crop rotation allows time between the planting dates of susceptible crops, which causes a decrease in the inoculum potential of soilborne plant pathogens to levels below an economic threshold by resident antagonistic soil microbial communities. Soilborne disease suppressiveness is an inherent characteristic of the physical, chemical, and/or biological structure of a particular soil which might be induced by agricultural practices and activities such as the cultivation of crops, or the addition of organisms or nutritional amendments, causing a change in the microfloral environment. Disturbances of soil ecosystems that impact on the normal functioning of microbial communities are potentially detrimental to soil formation, energy transfers, nutrient cycling, and long-term stability. In this regard, an overview of soil properties and processes indicated that the use of microbiological and biochemical soil properties, such as microbial biomass, the analysis of microbial functional diversity and microbial structural diversity by the quantification of community level physiological profiles and signature lipid biomarkers are useful as indicators of soil ecological stress or restoration properties because they are more responsive to small changes than physical and chemical characteristics. In this study, the relationship between physico-chemical characteristics, and different biological indicators of soil quality of agricultural soils conducive, suppressive, and neutral with respect to take-all disease of wheat as caused by the soilborne fungus Gaeumannomyces graminis var. tritici (Ggt), were investigated using various techniques. The effect of crop rotation on the functional and structural diversity of soils conducive to take-all disease was also investigated. Through the integration of quantitative and qualitative biological data as well as the physico-chemical characteristics of the various soils, the functional and structural diversity of microbial IV communities in the soils during different stadia of take-all disease of wheat were characterised. All results were evaluated statistically and the predominant physical and chemical characteristics that influenced the microbiological and biochemical properties of the agricultural soils during different stadia of take-all disease of wheat were identified using multivariate analyses. Although no significant difference @ > 0.05) could be observed between the various soils using conventional microbiological enumeration techniques, the incidence of Gliocladium spp. in suppressive soils was increased. Significant differences @ < 0.05) were observed between agricultural soils during different stadia of take-all disease of wheat. Although no clear distinction could be made between soils suppressive and neutral to take-all disease of wheat, soils suppressive and conducive to take-all disease of wheat differed substantially in their community level physiological profiles (CLPPs). Soils suppressive / neutral to take-all disease were characterised by enhanced utilisation of carboxylic acids, amino acids, and carbohydrates, while conducive soils were characterised by enhanced utilisation of carbohydrates. Shifts in the functional diversity of the associated microbial communities were possibly caused by the presence of Ggt and associated antagonistic fungal and bacterial populations in the various soils. It was evident that the relationships amongst the functionality of the microbial communities within the various soils had undergone changes through the different stages of development of take-all disease of wheat, thus implying different substrate utilisation capabilities of present soil microbial communities. Diversity indices were calculated as Shannon's diversity index (H') and substrate equitability (J) and were overall within the higher diversity range of 3.6 and 0.8, respectively, indicating the achievement of very high substrate diversity values in the various soils. A substantial percentage of the carbon sources were utilised, which contributed to the very high Shannon-Weaver substrate utilisation indices. Obtained substrate evenness (equitability) (J) indices indicated an existing high functional diversity. The functional diversity as observed during crop rotation, differed significantly (p < 0.05) from each other, implying different substrate utilisation capabilities of present soil microbial communities, which could possibly be ascribed to the excretion of root exudates by sunflowers and soybeans. Using the Sorenson's index, a clear distinction could be made between the degrees of substrate utilisation between microbial populations in soils conducive, suppressive, and neutral to take-all disease of wheat, as well as during crop rotation. Furthermore, the various soils could also be differentiated on the basis of the microbial community structure as determined by phospholipid fatty acid (PLFA) analysis. Soil suppressive to take-all disease of wheat differed significantly (p < 0.05) from soils conducive, and neutral to take-all disease of wheat, implying a shift in relationships amongst the structural diversity of microbial communities within the various soils. A positive association was observed between the microbial phospholipid fatty acid profiles, and dominant environmental variables of soils conducive, suppressive, and neutral to take-all disease of wheat. Soils conducive and neutral to take-all disease of wheat were characterised by high concentrations of manganese, as well as elevated concentrations of monounsaturated fatty acids, terminally branched saturated fatty acids, and polyunsaturated fatty acids which were indicative of Gram-negative bacteria, Gram-positive bacteria and micro eukaryotes (primarily fungi), respectively. These soils were also characterised by low concentrations of phosphorous, potassium, percentage organic carbon, and percentage organic nitrogen, as well as low soil pH. Soil suppressive to take-all disease of wheat was characterised by the elevated levels of estimated of biomass and elevated concentrations of normal saturated fatty acids, which is ubiquitous to micro-organisms. The concentration of normal saturated fatty acids in suppressive soils is indicative of a low structural diversity. This soil was also characterised by high concentrations of phosphorous, potassium, percentage organic carbon, and percentage organic nitrogen, as well as elevated soil pH. The relationship between PLFAs and agricultural soils was investigated using principal component analysis (PCA), redundancy analysis (RDA) and discriminant analysis (DA). Soil suppressive to take-all disease of wheat differed significantly (p < 0.05) from soils conducive, and neutral to take-all disease of wheat, implying a shift in relationships amongst the structural diversity of microbial communities within the various soils. A positive association was observed between the microbial phospholipid fatty acid profiles, and dominant environmental variables of soils conducive, suppressive, and neutral to take-all disease of wheat. Hierarchical cluster analysis of the major phospholipid fatty acid groups indicated that the structural diversity differed significantly between soils conducive, suppressive, and neutral to take-all disease of wheat caused by Gaeumannomyces graminis var. tritici. The results indicate that the microbial community functionality as well as the microbial community structure was significantly influenced by the presence of take-all disease of wheat caused by Gaeumannomyces graminis var. tritici, and that the characterisation of microbial functional and structural diversity by analysis of community level physiological profiles and phospholipid fatty acid analysis, respectively, could be successfully used as an assessment criteria for the evaluation of agricultural soils conducive, suppressive, and neutral to take-all disease of wheat, as well as in crop rotation systems. This methodology might be of significant value in assisting in the management and evaluation of agricultural soils subject to the prevalence of other soilborne diseases. / Thesis (M.Sc. (Microbiology))--North-West University, Potchefstroom Campus, 2004.

Soil microbial communities

Gaeumannomyces graminis var. tritici

Take-all disease

Crop rotation

Diversity indices

Soil microbial community structure

Phospholipid fatty acids (PFLAs)

Change in the Structure of Soil Microbial Communities in Response to Waste Amendments

Buckley, Elan

January 2020

Soil microbial communities are affected extensively by addition of amendments to their environment. Of particular concern is the addition of poultry litter, which contains a substantial C, energy, and nutrient supply, but also antibiotic resistance genes (ARG), antimicrobials, and a multitude of microbial species. This project seeks to primarily assess if there is a change in bacterial community structure in response to poultry litter amendments to pasture land across geographically independent land across northern Georgia. It may be that changes in the relative abundance of bacterial communities also result in alteration in ARGs, and the community resistance to antibiotics (“resistome”) which in turn increases the potential threat of antibiotic resistance genes. While another part of this study will determine changes in integrons and specific ARGs, this project will focus on changes in bacterial communities and the potential functional changes in the community, which in turn have consequences for ARG levels and its horizontal transfer to various members of the soil community. Addition of waste from livestock is a historical method for increasing nutrients needed in the soil for the cultivation of crops, and in turn causes pronounced shifts in soil microbial communities due to the addition of large amounts of carbon, nutrients, foreign microbes, and other material. This study is unique because it utilizes a novel and relatively large landscape-scale to determine if there are discernable and repeatable patterns of bacterial community structure change in response to amendment regardless of exact soil type or source of chicken litter amendment. In the future, these data can also provide insight into the changes in the relative abundance antibiotic related genes associated with community change. / M.S. / Soil is complicated, both in terms of its physical makeup and the organisms that live inside of it. Predicting changes in soil based on the addition of foreign material such as chemicals or biological waste is not an easy process, and whether or not it is even possible to reliably predict those changes is a matter of some dispute. This study is designed to illustrate that such changes can in fact be reliably and consistently predicted even with regard to the addition of complicated materials to the soil. In this study, specifically, the material in question is chicken litter. A mix of the bedding and waste produced by chickens, litter is commonly handled by composting and is added to soil in farms as a fertilizer rich in organic matter. It is possible to point at specific elements of the soil such as the chemistry and bacteria and see how it is changed with the addition of chicken litter, which allows us to determine the nature and extent of the change that chicken litter has on soil. This study is conducted on a larger scale than similar experiments conducted in the past, making it apparent that these relationships exist on a repeated basis. It is the object of this study to pave the way and make it easier for scientists in the future to determine these relationships in other unique contexts.

16S rRNA

alpha and beta diversity

ANCOM pairwise comparisons

ANOSIM

Bacilli

chicken litter

Clostridia

DNA extraction

Firmicutes

metagenomics

microbial community shift

MiSeq Illumina

PERMANOVA

soil microbial community

taxonomy

UniFrac

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