Your search keyword '"Gary L. Andersen"' showing total 9 results

1. Microbial secondary succession in a chronosequence of chalk grasslands

Author

Hannes A. Gamper, George A. Kowalchuk, Etienne Yergeau, Todd Z. DeSantis, Johannes A. van Veen, Eiko E. Kuramae, Yvette M. Piceno, Gary L. Andersen, Eoin L. Brodie, Animal Ecology, Systems Ecology, Terrestrial Microbial Ecology (TME), and Microbial Ecology (ME)

Subjects

Secondary succession, Bacteria, biology, Ecology, Chronosequence, Biodiversity, Ecological succession, Vegetation, biology.organism_classification, Polymerase Chain Reaction, Microbiology, Soil pH, Gemmatimonadetes, Ecosystem, Soil Microbiology, Ecology, Evolution, Behavior and Systematics, Netherlands, Acidobacteria

Abstract

Although secondary succession has been studied extensively, we have little knowledge of the succession of soil-borne microbial communities. In this study, we therefore examined the structures of the microbial communities across two separate chronosequences of chalk grasslands in Limburg, the Netherlands, which are at different stages of secondary succession after being abandoned for between 17 and 66 years. Arable fields were also included in the investigation as non-abandoned references. Changes in the soil-borne microbial communities, as determined by phylogenetic microarray and quantitative PCR methodologies, were correlated with the prevailing environmental conditions related to vegetation and soil biochemistry. We observed clear patterns of microbial secondary succession related to soil age, pH and phosphate status, as exemplified by the overrepresentation of Verrucomicrobia, Acidobacteria, Gemmatimonadetes, and α-, δ- and ε-Proteobacteria at late successional stages. Moreover, effects of secondary succession versus changes in soil pH could be resolved, with pH significantly altering the trajectory of microbial succession. © 2010 International Society for Microbial Ecology All rights reserved.

Published

2010

2. Selective progressive response of soil microbial community to wild oat roots

Author

Todd Z. DeSantis, Kristen M. DeAngelis, Gary L. Andersen, Eoin L. Brodie, Mary K. Firestone, and Steven E. Lindow

Subjects

Rhizosphere, Avena, Bacteria, Soil test, biology, Firmicutes, Colony Count, Microbial, Verrucomicrobia, Bulk soil, Soil classification, Biodiversity, Microarray Analysis, biology.organism_classification, Plant Roots, Polymerase Chain Reaction, complex mixtures, Microbiology, Actinobacteria, RNA, Bacterial, RNA, Ribosomal, 16S, Soil water, Botany, Soil Microbiology, Ecology, Evolution, Behavior and Systematics, Oligonucleotide Array Sequence Analysis

Abstract

Roots moving through soil induce physical and chemical changes that differentiate rhizosphere from bulk soil, and the effects of these changes on soil microorganisms have long been a topic of interest. The use of a high-density 16S rRNA microarray (PhyloChip) for bacterial and archaeal community analysis has allowed definition of the populations that respond to the root within the complex grassland soil community; this research accompanies compositional changes reported earlier, including increases in chitinase- and protease-specific activity, cell numbers and quorum sensing signal. PhyloChip results showed a significant change compared with bulk soil in relative abundance for 7% of the total rhizosphere microbial community (147 of 1917 taxa); the 7% response value was confirmed by16S rRNA terminal restriction fragment length polymorphism analysis. This PhyloChip-defined dynamic subset was comprised of taxa in 17 of the 44 phyla detected in all soil samples. Expected rhizosphere-competent phyla, such as Proteobacteria and Firmicutes, were well represented, as were less-well-documented rhizosphere colonizers including Actinobacteria, Verrucomicrobia and Nitrospira. Richness of Bacteroidetes and Actinobacteria decreased in soil near the root tip compared with bulk soil, but then increased in older root zones. Quantitative PCR revealed rhizosphere abundance of beta-Proteobacteria and Actinobacteria at about 10(8) copies of 16S rRNA genes per g soil, with Nitrospira having about 10(5) copies per g soil. This report demonstrates that changes in a relatively small subset of the soil microbial community are sufficient to produce substantial changes in functions observed earlier in progressively more mature rhizosphere zones.

Published

2008

3. Core-satellite populations and seasonality of water meter biofilms in a metropolitan drinking water distribution system

Author

Chiachi Hwang, Mark W. LeChevallier, Fangqiong Ling, Wen Tso Liu, and Gary L. Andersen

Subjects

0301 basic medicine, Biomass (ecology), Operational taxonomic unit, Bacteria, Geomicrobiology, Ecology, Drinking Water, Community structure, Methylophilaceae, Biology, biology.organism_classification, Bacterial Physiological Phenomena, Microbiology, 03 medical and health sciences, 030104 developmental biology, Tap water, Biofilms, Water Quality, Species evenness, Original Article, Water quality, Seasons, Cities, Ecology, Evolution, Behavior and Systematics

Abstract

Drinking water distribution systems (DWDSs) harbor the microorganisms in biofilms and suspended communities, yet the diversity and spatiotemporal distribution have been studied mainly in the suspended communities. This study examined the diversity of biofilms in an urban DWDS, its relationship with suspended communities and its dynamics. The studied DWDS in Urbana, Illinois received conventionally treated and disinfected water sourced from the groundwater. Over a 2-year span, biomass were sampled from household water meters (n=213) and tap water (n=20) to represent biofilm and suspended communities, respectively. A positive correlation between operational taxonomic unit (OTU) abundance and occupancy was observed. Examined under a 'core-satellite' model, the biofilm community comprised 31 core populations that encompassed 76.7% of total 16 S rRNA gene pyrosequences. The biofilm communities shared with the suspended community highly abundant and prevalent OTUs, which related to methano-/methylotrophs (i.e., Methylophilaceae and Methylococcaceae) and aerobic heterotrophs (Sphingomonadaceae and Comamonadaceae), yet differed by specific core populations and lower diversity and evenness. Multivariate tests indicated seasonality as the main contributor to community structure variation. This pattern was resilient to annual change and correlated to the cyclic fluctuations of core populations. The findings of a distinctive biofilm community assemblage and methano-/methyltrophic primary production provide critical insights for developing more targeted water quality monitoring programs and treatment strategies for groundwater-sourced drinking water systems.

Published

2015

4. Tackling the minority: sulfate-reducing bacteria in an archaea-dominated subsurface biofilm

Author

Hoi-Ying N. Holman, Giovanni Birarda, Todd Z. DeSantis, Yvette M. Piceno, Hans A. Bechtel, Kasthuri Venkateswaran, Maria Sonnleitner, Alexander J. Probst, Gary L. Andersen, and Christine Moissl-Eichinger

Subjects

DNA, Bacterial, Microorganism, Microbial metabolism, Bacterial Physiological Phenomena, Microbiology, Microbial ecology, RNA, Ribosomal, 16S, Spectroscopy, Fourier Transform Infrared, Sulfate-reducing bacteria, Hydrogensulfite Reductase, Ecology, Evolution, Behavior and Systematics, In Situ Hybridization, Fluorescence, Phylogeny, biology, Bacteria, Biofilm, Natural Springs, Biodiversity, biology.organism_classification, Archaea, Environmental biotechnology, Environmental chemistry, Biofilms, Original Article

Abstract

Archaea are usually minor components of a microbial community and dominated by a large and diverse bacterial population. In contrast, the SM1 Euryarchaeon dominates a sulfidic aquifer by forming subsurface biofilms that contain a very minor bacterial fraction (5%). These unique biofilms are delivered in high biomass to the spring outflow that provides an outstanding window to the subsurface. Despite previous attempts to understand its natural role, the metabolic capacities of the SM1 Euryarchaeon remain mysterious to date. In this study, we focused on the minor bacterial fraction in order to obtain insights into the ecological function of the biofilm. We link phylogenetic diversity information with the spatial distribution of chemical and metabolic compounds by combining three different state-of-the-art methods: PhyloChip G3 DNA microarray technology, fluorescence in situ hybridization (FISH) and synchrotron radiation-based Fourier transform infrared (SR-FTIR) spectromicroscopy. The results of PhyloChip and FISH technologies provide evidence for selective enrichment of sulfate-reducing bacteria, which was confirmed by the detection of bacterial dissimilatory sulfite reductase subunit B (dsrB) genes via quantitative PCR and sequence-based analyses. We further established a differentiation of archaeal and bacterial cells by SR-FTIR based on typical lipid and carbohydrate signatures, which demonstrated a co-localization of organic sulfate, carbonated mineral and bacterial signatures in the biofilm. All these results strongly indicate an involvement of the SM1 euryarchaeal biofilm in the global cycles of sulfur and carbon and support the hypothesis that sulfidic springs are important habitats for Earth's energy cycles. Moreover, these investigations of a bacterial minority in an Archaea-dominated environment are a remarkable example of the great power of combining highly sensitive microarrays with label-free infrared imaging.

Published

2012

5. Compartmentalized microbial composition, oxygen gradients and nitrogen fixation in the gut of Odontotaenius disjunctus

Author

Javier A. Ceja-Navarro, Gary L. Andersen, Stephanie R Gross, Thomas D Bruns, Meredith Blackwell, Nhu H. Nguyen, Donald J. Herman, Ulas Karaoz, Jennifer Pett-Ridge, and Eoin L. Brodie

Subjects

Molecular Sequence Data, Microbiology, Actinobacteria, Microbial ecology, Nitrogen Fixation, RNA, Ribosomal, 16S, Botany, Animals, Ecology, Evolution, Behavior and Systematics, Phylogeny, biology, Bacteria, Ecology, Bacteroidetes, Nitrogenase, Foregut, Biodiversity, Gene Expression Regulation, Bacterial, biology.organism_classification, Archaea, Odontotaenius disjunctus, Coleoptera, Gastrointestinal Tract, Oxygen, Nitrogen fixation, Original Article, Oxidoreductases

Abstract

Coarse woody debris is an important biomass pool in forest ecosystems that numerous groups of insects have evolved to take advantage of. These insects are ecologically important and represent useful natural analogs for biomass to biofuel conversion. Using a range of molecular approaches combined with microelectrode measurements of oxygen, we have characterized the gut microbiome and physiology of Odontotaenius disjunctus, a wood-feeding beetle native to the eastern United States. We hypothesized that morphological and physiological differences among gut regions would correspond to distinct microbial populations and activities. In fact, significantly different communities were found in the foregut (FG), midgut (MG)/posterior hindgut (PHG) and anterior hindgut (AHG), with Actinobacteria and Rhizobiales being more abundant toward the FG and PHG. Conversely, fermentative bacteria such as Bacteroidetes and Clostridia were more abundant in the AHG, and also the sole region where methanogenic Archaea were detected. Although each gut region possessed an anaerobic core, micron-scale profiling identified radial gradients in oxygen concentration in all regions. Nitrogen fixation was confirmed by (15)N2 incorporation, and nitrogenase gene (nifH) expression was greatest in the AHG. Phylogenetic analysis of nifH identified the most abundant transcript as related to Ni-Fe nitrogenase of a Bacteroidetes species, Paludibacter propionicigenes. Overall, we demonstrate not only a compartmentalized microbiome in this beetle digestive tract but also sharp oxygen gradients that may permit aerobic and anaerobic metabolism to occur within the same regions in close proximity. We provide evidence for the microbial fixation of N2 that is important for this beetle to subsist on woody biomass.

Published

2012

6. The phylogenetic composition and structure of soil microbial communities shifts in response to elevated carbon dioxide

Author

Zhenmei Lu, Peter B. Reich, Sarah E. Hobbie, Jizhong Zhou, Gary L. Andersen, Zhili He, Ye Deng, Todd Z. DeSantis, Meiying Xu, and Yvette M. Piceno

Subjects

biology, Bacteria, Ecology, Firmicutes, Verrucomicrobia, Biodiversity, Carbon Dioxide, Plants, biology.organism_classification, Bacterial Physiological Phenomena, Microbiology, Actinobacteria, Soil, Microbial population biology, Crenarchaeota, Botany, Original Article, Species richness, Soil microbiology, Ecology, Evolution, Behavior and Systematics, Phylogeny, Soil Microbiology, Acidobacteria

Abstract

One of the major factors associated with global change is the ever-increasing concentration of atmospheric CO(2). Although the stimulating effects of elevated CO(2) (eCO(2)) on plant growth and primary productivity have been established, its impacts on the diversity and function of soil microbial communities are poorly understood. In this study, phylogenetic microarrays (PhyloChip) were used to comprehensively survey the richness, composition and structure of soil microbial communities in a grassland experiment subjected to two CO(2) conditions (ambient, 368 p.p.m., versus elevated, 560 p.p.m.) for 10 years. The richness based on the detected number of operational taxonomic units (OTUs) significantly decreased under eCO(2). PhyloChip detected 2269 OTUs derived from 45 phyla (including two from Archaea), 55 classes, 99 orders, 164 families and 190 subfamilies. Also, the signal intensity of five phyla (Crenarchaeota, Chloroflexi, OP10, OP9/JS1, Verrucomicrobia) significantly decreased at eCO(2), and such significant effects of eCO(2) on microbial composition were also observed at the class or lower taxonomic levels for most abundant phyla, such as Proteobacteria, Firmicutes, Actinobacteria, Bacteroidetes and Acidobacteria, suggesting a shift in microbial community composition at eCO(2). Additionally, statistical analyses showed that the overall taxonomic structure of soil microbial communities was altered at eCO(2). Mantel tests indicated that such changes in species richness, composition and structure of soil microbial communities were closely correlated with soil and plant properties. This study provides insights into our understanding of shifts in the richness, composition and structure of soil microbial communities under eCO(2) and environmental factors shaping the microbial community structure.

Published

2011

7. Bacterial community structure corresponds to performance during cathodic nitrate reduction

Author

Kelly C. Wrighton, Yvette M. Piceno, John D. Coates, Nico Boon, Korneel Rabaey, Rebecca A. Daly, Bernardino Virdis, Peter Clauwaert, Gary L. Andersen, and S Read

Subjects

DNA, Bacterial, Microbial fuel cell, Denitrification, DNA, Complementary, NITROSOMONAS-EUROPAEA, Firmicutes, Bioelectric Energy Sources, FUNCTIONAL REDUNDANCY, URANIUM, Biology, ECOLOGY, PhyloChip, ELECTRICITY, Microbiology, DNA, Ribosomal, microbial fuel cell, Denitrifying bacteria, Microbial ecology, nitrate, RNA, Ribosomal, 16S, Botany, Electrodes, Ecology, Evolution, Behavior and Systematics, In Situ Hybridization, Fluorescence, SLUDGE, Nitrates, Bacteria, Biology and Life Sciences, bioelectrochemical system, Biodiversity, biology.organism_classification, chemolithotrophic, NITRIFIER DENITRIFICATION, Anode, Phylogenetic diversity, Environmental chemistry, Biofilms, MICROBIAL FUEL-CELLS, BIODIVERSITY, Proteobacteria, RIBOSOMAL-RNA, Oxidation-Reduction

Abstract

Microbial fuel cells (MFCs) have applications other than electricity production, including the capacity to power desirable reactions in the cathode chamber. However, current knowledge of the microbial ecology and physiology of biocathodes is minimal, and as a result more research dedicated to understanding the microbial communities active in cathode biofilms is required. Here we characterize the microbiology of denitrifying bacterial communities stimulated by reducing equivalents generated from the anodic oxidation of acetate. We analyzed biofilms isolated from two types of cathodic denitrification systems: (1) a loop format where the effluent from the carbon oxidation step in the anode is subjected to a nitrifying reactor which is fed to the cathode chamber and (2) an alternative non-loop format where anodic and cathodic feed streams are separated. The results of our study indicate the superior performance of the loop reactor in terms of enhanced current production and nitrate removal rates. We hypothesized that phylogenetic or structural features of the microbial communities could explain the increased performance of the loop reactor. We used PhyloChip with 16S rRNA (cDNA) and fluorescent in situ hybridization to characterize the active bacterial communities. Our study results reveal a greater richness, as well as an increased phylogenetic diversity, active in denitrifying biofilms than was previously identified in cathodic systems. Specifically, we identified Proteobacteria, Firmicutes and Chloroflexi members that were dominant in denitrifying cathodes. In addition, our study results indicate that it is the structural component, in terms of bacterial richness and evenness, rather than the phylogenetic affiliation of dominant bacteria, that best corresponds to cathode performance.

Published

2010

8. Bacterial diversity and White Plague Disease-associated community changes in the Caribbean coral Montastraea faveolata

Author

Yvette M. Piceno, Todd Z. DeSantis, Shinichi Sunagawa, Gary L. Andersen, Michael K. DeSalvo, Ernesto Weil, Christian R. Voolstra, Eoin L. Brodie, and Mónica Medina

Subjects

DNA, Bacterial, food.ingredient, Library, Coral, Molecular Sequence Data, Zoology, Biology, Microbiology, DNA, Ribosomal, Bacterial genetics, food, RNA, Ribosomal, 16S, Sequence Homology, Nucleic Acid, Animals, Cluster Analysis, Rhodobacteraceae, Ecology, Evolution, Behavior and Systematics, Phylogeny, Bacteria, Campylobacteraceae, Genes, rRNA, Bacterial Infections, Biodiversity, Sequence Analysis, DNA, biology.organism_classification, Anthozoa, Microarray Analysis, Aurantimonas, Holobiont, RNA, Bacterial, Caribbean Region

Abstract

Increasing evidence confirms the crucial role bacteria and archaea play within the coral holobiont, that is, the coral host and its associated microbial community. The bacterial component constitutes a community of high diversity, which appears to change in structure in response to disease events. In this study, we highlight the limitation of 16S rRNA gene (16S rDNA) clone library sequencing as the sole method to comprehensively describe coral-associated communities. This limitation was addressed by combining a high-density 16S rRNA gene microarray with, clone library sequencing as a novel approach to study bacterial communities in healthy versus diseased corals. We determined an increase in diversity as well as a significant shift in community structure in Montastraea faveolata colonies displaying phenotypic signs of White Plague Disease type II (WPD-II). An accumulation of species that belong to families that include known coral pathogens (Alteromonadaceae, Vibrionaceae), bacteria previously isolated from diseased, stressed or injured marine invertebrates (for example, Rhodobacteraceae), and other species (for example, Campylobacteraceae) was observed. Some of these species were also present in healthy tissue samples, but the putative primary pathogen, Aurantimonas corallicida, was not detected in any sample by either method. Although an ecological succession of bacteria during disease progression after causation by a primary agent represents a possible explanation for our observations, we also discuss the possibility that a disease of yet to be determined etiology may have affected M. faveolata colonies and resulted in (or be a result of) an increase in opportunistic pathogens.

Published

2009

9. A novel ecological role of the Firmicutes identified in thermophilic microbial fuel cells

Author

Todd Z. DeSantis, Philip Hugenholtz, John D. Coates, Eoin L. Brodie, Karrie A. Weber, Kelly C. Wrighton, Falk Warnecke, Peter Agbo, and Gary L. Andersen

Subjects

DNA, Bacterial, Microbial fuel cell, Hot Temperature, Library, Firmicutes, Bioelectric Energy Sources, Molecular Sequence Data, Gram-Positive Bacteria, Microbiology, DNA, Ribosomal, Electricity, RNA, Ribosomal, 16S, Sequence Homology, Nucleic Acid, Ecology, Evolution, Behavior and Systematics, Phylogeny, biology, Ecology, Thermophile, Genes, rRNA, Sequence Analysis, DNA, Ribosomal RNA, biology.organism_classification, 16S ribosomal RNA, Microarray Analysis, RNA, Bacterial, Bacteria, Mesophile

Abstract

Significant effort is currently focused on microbial fuel cells (MFCs) as a source of renewable energy. Most studies concentrate on operation at mesophilic temperatures. However, anaerobic digestion studies have reported on the superiority of thermophilic operation and demonstrated a net energy gain in terms of methane yield. As such, our studies focused on MFC operation and microbiology at 55 degrees C. Over a 100-day operation, these MFCs were stable and achieved a power density of 37 mW m(-2) with a coulombic efficiency of 89%. To infer activity and taxonomic identity of dominant members of the electricity-producing community, we performed phylogenetic microarray and clone library analysis with small subunit ribosomal RNA (16S rRNA) and ribosomal RNA gene (16S rDNA). The results illustrated the dominance (80% of clone library sequences) of the Firmicutes in electricity production. Similarly, rRNA sequences from Firmicutes accounted for 50% of those taxa that increased in relative abundance from current-producing MFCs, implying their functional role in current production. We complemented these analyses by isolating the first organisms from a thermophilic MFC. One of the isolates, a Firmicutes Thermincola sp. strain JR, not only produced more current than known organisms (0.42 mA) in an H-cell system but also represented the first demonstration of direct anode reduction by a member of this phylum. Our research illustrates the importance of using a variety of molecular and culture-based methods to reliably characterize bacterial communities. Consequently, we revealed a previously unidentified functional role for Gram-positive bacteria in MFC current generation.

Published

2008