Your search keyword '"Anna Christine Trego"' showing total 7 results

1. Novel microbial syntrophies identified by longitudinal metagenomics

Author

Orkun S. Soyer, Christopher Quince, Fred Farrell, Sebastien Raguideau, Gavin Collins, and Anna Christine Trego

Subjects

Facultative, biology, Microbial population biology, Evolutionary biology, Metagenomics, Thermoplasmata, Thermococci, Sugar transport, biology.organism_classification, Genome

Abstract

Identifying species interactions in a microbial community and how this relates to community function is a key challenge. Towards addressing this challenge, we present here an extensive genome-resolved, longitudinal dataset and associated metadata. We collected weekly samples of microbial communities and recorded operating conditions from industrial methane producing anaerobic digestion reactors for a year. This allowed us to recover 2240 dereplicated metagenome assembled genomes (dMAGs), together with their coverage dynamics and functional annotations from which functional traits were inferred. Of these dMAGs, 1910 were novel species, with 22 representing novel orders and classes. Methanogenic communities are expected to be strongly structured by syntrophic and other associations between the methanogens and syntrophs that produce their substrates. We identified 450 potential syntrophic dMAGs by searching for pairs of methanogenic and non-methanogenic dMAGs that had highly correlated time-series. Genomes of potential syntrophs were enriched for oxidoreductases and sugar transport genes and there was a strong taxonomic signal in their associations with methanogens. Of particular note, we found that Bathyarchaeiea associated specifically with methanogens from the Thermoplasmata, and Thermococci classes. Same syntrophic associations were only rarely observed across multiple reactors, suggesting that syntrophies might be facultative, with particular strains within a species forming syntrophic associations only sometimes and not necessarily always with the same methanogenic partner. The presented results show that longitudinal metagenomics is a highly valuable approach for identifying species and their interactions in microbial communities.One Sentence SummaryLongitudinal study of microbial communities identifies novel species and predicts their interactions and role in community function.

Published

2021

2. Combined Stochastic and Deterministic Processes Drive Community Assembly of Anaerobic Microbiomes During Granule Flotation

Author

Anna Christine Trego, Thérèse Mahony, Florence Abram, Vincent O'Flaherty, Paul G. McAteer, Corine Nzeteu, and Umer Zeeshan Ijaz

Subjects

Microbiology (medical), anaerobic digestion, dairy wastewater, media_common.quotation_subject, Biology, Microbiology, Methanosaeta, Competition (biology), 03 medical and health sciences, Microbiome, low-temperature anaerobic digestion, 030304 developmental biology, media_common, Original Research, 0303 health sciences, 030306 microbiology, Granule (cell biology), sludge flotation, biology.organism_classification, 6. Clean water, QR1-502, Anaerobic digestion, Homogeneous, Amplicon sequencing, Biological dispersal, community assembly, Biochemical engineering

Abstract

Advances in null-model approaches have resulted in a deeper understanding of community assembly mechanisms for a variety of complex microbiomes. One under-explored application is assembly of communities from the built-environment, especially during process disturbances. Anaerobic digestion for biological wastewater treatment is often underpinned by retaining millions of active granular biofilm aggregates. Flotation of granules is a major problem, resulting in process failure. Anaerobic aggregates were sampled from three identical bioreactors treating dairy wastewater. Microbiome structure was analysed using qPCR and 16S rRNA gene amplicon sequencing from DNA and cDNA. A comprehensive null-model approach quantified assembly mechanisms of floating and settled communities. Significant differences in diversity were observed between floating and settled granules, in particular, we highlight the changing abundances of Methanosaeta and Lactococcus. Both stochastic and deterministic processes were important for community assembly. Homogeneous selection was the primary mechanism for all categories, but dispersal processes also contributed. The lottery model was used to identify clade-level competition driving community assembly. Lottery “winners” were identified with different winners between floating and settled groups. Some groups changed their winner status when flotation occurred. Spirochaetaceae, for example, was only a winner in settled biomass (cDNA-level) and lost its winner status during flotation. Alternatively, Arcobacter butzerli gained winner status during flotation. This analysis provides a deeper understanding of changes that occur during process instabilities and identified groups which may be washed out—an important consideration for process control.

Published

2021

3. Size Shapes the Active Microbiome of Methanogenic Granules, Corroborating a Biofilm Life Cycle

Author

Umer Zeeshan Ijaz, Sarah O’Sullivan, Simon Mills, Gavin Collins, Anna Christine Trego, and Christopher Quince

Subjects

anaerobic digestion, Methanobacterium, Physiology, Methanogenesis, 010501 environmental sciences, 01 natural sciences, Biochemistry, Microbiology, biofilm, 03 medical and health sciences, Microbial ecology, Genetics, Molecular Biology, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 0105 earth and related environmental sciences, 0303 health sciences, biology, Applied and Environmental Science, Chemistry, Granule (cell biology), Biofilm, biology.organism_classification, QR1-502, Computer Science Applications, Anaerobic digestion, Microbial population biology, methanogenic granules, Modeling and Simulation, community assembly, microbial community assembly, Research Article, Archaea

Abstract

Biological wastewater conversion processes collectively constitute one of the single biggest worldwide applications of microbial communities. There is an obvious requirement, therefore, to study the microbial systems central to the success of such technologies. Methanogenic granules, in particular, are architecturally fascinating biofilms that facilitate highly organized cooperation within the metabolic network of the anaerobic digestion (AD) process and, thus, are especially intriguing model systems for microbial ecology. This study, in a way not previously reported, provoked syntrophic and methanogenic activity and the structure of the microbial community, using specific substrates targeting the key trophic groups in AD. Unexpectedly, granule size more strongly than substrate shaped the active portion of the microbial community. Importantly, the findings suggest the size, or age, of granules inherently shapes the active microbiome linked to a life cycle. This provides exciting insights into the function of, and the potential for additional modeling of biofilm development in, methanogenic granules., Methanogenic archaea are key players in cycling organic matter in nature but also in engineered waste treatment systems, where they generate methane, which can be used as a renewable energy source. In such systems in the built environment, complex methanogenic consortia are known to aggregate into highly organized, spherical granular biofilms comprising the interdependent microbial trophic groups mediating the successive stages of the anaerobic digestion (AD) process. This study separated methanogenic granules into a range of discrete size fractions, hypothesizing different biofilm growth stages, and separately supplied each with specific substrates to stimulate the activity of key AD trophic groups, including syntrophic acid oxidizers and methanogens. Rates of specific methanogenic activity were measured, and amplicon sequencing of 16S rRNA gene transcripts was used to resolve phylotranscriptomes across the series of size fractions. Increased rates of methane production were observed in each of the size fractions when hydrogen was supplied as the substrate compared with those of volatile fatty acids (acetate, propionate, and butyrate). This was connected to a shift toward hydrogenotrophic methanogenesis dominated by Methanobacterium and Methanolinea. Interestingly, the specific active microbiomes measured in this way indicated that size was significantly more important than substrate in driving the structure of the active community in granules. Multivariate integration studywise discriminant analysis identified 56 genera shaping changes in the active community across both substrate and size. Half of those were found to be upregulated in the medium-sized granules, which were also the most active and potentially of the most important size, or life stage, for precision management of AD systems. IMPORTANCE Biological wastewater conversion processes collectively constitute one of the single biggest worldwide applications of microbial communities. There is an obvious requirement, therefore, to study the microbial systems central to the success of such technologies. Methanogenic granules, in particular, are architecturally fascinating biofilms that facilitate highly organized cooperation within the metabolic network of the anaerobic digestion (AD) process and, thus, are especially intriguing model systems for microbial ecology. This study, in a way not previously reported, provoked syntrophic and methanogenic activity and the structure of the microbial community, using specific substrates targeting the key trophic groups in AD. Unexpectedly, granule size more strongly than substrate shaped the active portion of the microbial community. Importantly, the findings suggest the size, or age, of granules inherently shapes the active microbiome linked to a life cycle. This provides exciting insights into the function of, and the potential for additional modeling of biofilm development in, methanogenic granules.

Published

2020

4. Growth and Break-Up of Methanogenic Granules Suggests Mechanisms for Biofilm and Community Development

Author

Anna Christine Trego, Evan Galvin, Conor Sweeney, Sinéad Dunning, Cillian Murphy, Simon Mills, Corine Nzeteu, Christopher Quince, Stephanie Connelly, Umer Zeeshan Ijaz, and Gavin Collins

Subjects

anaerobic digestion, sludge granules, Microbiology (medical), Methanobacterium, Microorganism, lcsh:QR1-502, microbial communities, Microbiology, lcsh:Microbiology, 03 medical and health sciences, Granulation, Bioreactor, methanogens, Food science, wastewater, Original Research, 030304 developmental biology, 0303 health sciences, biology, 030306 microbiology, Chemistry, Granule (cell biology), Biofilm, biology.organism_classification, Desulfovibrio, Anaerobic digestion, biofilms

Abstract

Methanogenic sludge granules are densely packed, small, spherical biofilms found in anaerobic digesters used to treat industrial wastewaters, where they underpin efficient organic waste conversion and biogas production. Each granule theoretically houses representative microorganisms from all of the trophic groups implicated in the successive and interdependent reactions of the anaerobic digestion (AD) process. Information on exactly how methanogenic granules develop, and their eventual fate will be important for precision management of environmental biotechnologies. Granules from a full-scale bioreactor were size-separated into small (0.6–1 mm), medium (1–1.4 mm), and large (1.4–1.8 mm) size fractions. Twelve laboratory-scale bioreactors were operated using either small, medium, or large granules, or unfractionated sludge. After >50 days of operation, the granule size distribution in each of the small, medium, and large bioreactor sets had diversified beyond—to both bigger and smaller than—the size fraction used for inoculation. Interestingly, extra-small (XS

Published

2020

5. Reactor configuration influences microbial community structure during high-rate, low-temperature anaerobic treatment of dairy wastewater

Author

Florence Abram, Paul G. McAteer, Camilla Thorn, Thérèse Mahony, Vincent O'Flaherty, and Anna Christine Trego

Subjects

0106 biological sciences, Environmental Engineering, Lactococcus, Bioengineering, Wastewater, 010501 environmental sciences, Waste Disposal, Fluid, 01 natural sciences, Methanosaeta, Bioreactors, RNA, Ribosomal, 16S, 010608 biotechnology, Bioreactor, Anaerobic treatment, Anaerobiosis, Waste Management and Disposal, 0105 earth and related environmental sciences, Sewage, biology, Renewable Energy, Sustainability and the Environment, Chemistry, Microbiota, Temperature, General Medicine, biology.organism_classification, 16S ribosomal RNA, Pulp and paper industry, Anaerobic digestion, Microbial population biology

Abstract

Low temperature anaerobic digestion remains in its infancy, despite increasing interest for the treatment of complex wastewaters. In this study, the feasibility of low-temperature anaerobic treatment of dairy wastewater was assessed during a 443-day laboratory-scale bioreactor trial. The bioreactors were operated in triplicate at organic loading rates of 7.5–9 kgCODm−3d−1 throughout five operational phases. The structure of the microbial community was analysed using quantitative real-time PCR and amplicon sequencing of 16S rRNA genes from DNA and rRNA. The results indicated that low-temperature treatment of dairy wastewater is feasible at 15 °C, but that reactor configuration remains extremely important. The upflow anaerobic sludge bed (UASB) configuration out-performed the expanded granular sludge bed (EGSB)-based configurations. Decreased temperatures resulted in significant reductions in microbiome diversity. Methanosaeta was identified as a dominant genus throughout the trial, while Lactococcus was identified as an important bacterial genus at low-temperatures. However, the relative abundance of Lactococcus was significantly influenced by reactor configuration.

Published

2020

6. De novo growth of methanogenic granules indicates a biofilm life-cycle with complex ecology

Author

Christopher Quince, Stephanie Connelly, Sinéad Dunning, Anna Christine Trego, Umer Zeeshan Ijaz, Evan Galvin, Gavin Collins, Conor Sweeney, Simon Mills, Corine Nzeteu, and Cillian Murphy

Subjects

0303 health sciences, biology, 030306 microbiology, Chemistry, Microorganism, Granule (cell biology), Biofilm, Biodegradable waste, biology.organism_classification, Desulfovibrio, 6. Clean water, 03 medical and health sciences, Anaerobic digestion, Microbial ecology, 13. Climate action, Bioreactor, Food science, 030304 developmental biology

Abstract

Methanogenic sludge granules are densely packed, small (diameter, approx. 0.5-2.0 mm) spherical biofilms found in anaerobic digesters used to treat industrial wastewaters, where they underpin efficient organic waste conversion and biogas production. A single digester contains millions of individual granules, each of which is a highly-organised biofilm comprised of a complex consortium of likely billions of cells from across thousands of species – but not all granules are identical. Whilst each granule theoretically houses representative microorganisms from all of the trophic groups implicated in the successive and interdependent reactions of the anaerobic digestion process, parallel granules function side-by-side in digesters to provide a ‘meta-organism’ of sorts. Granules from a full-scale bioreactor were size-separated into small, medium and large granules. Laboratory-scale bioreactors were operated using only small (0.6–1 mm), medium (1–1.4 mm) or large (1.4–1.8 mm) granules, or unfractionated (naturally distributed) sludge. After >50 days of operation, the granule size distribution in each of the small, medium and large bioreactor types had diversified beyond – to both bigger and smaller than – the size fraction used for inoculation. ‘New’ granules were analysed by studying community structure based on high-throughput 16S rRNA gene sequencing.Methanobacterium,Aminobacterium,PropionibacteriaceaeandDesulfovibriorepresented the majority of the community in new granules. H2-using, and not acetoclastic, methanogens appeared more important, and were associated with abundant syntrophic bacteria. Multivariate integration analyses identified distinct discriminant taxa responsible for shaping the microbial communities in different-sized granules, and along with alpha diversity data, indicated a possible biofilm life cycle.ImportanceMethanogenic granules are spherical biofilms found in the built environment, where despite their importance for anaerobic digestion of wastewater in bioreactors, little is understood about the fate of granules across their entire life. Information on exactly how, and at what rates, methanogenic granules develop will be important for more precise and innovative management of environmental biotechnologies. Microbial aggregates also spark interest as subjects in which to study fundamental concepts from microbial ecology, including immigration and species sorting affecting the assembly of microbial communities. This experiment is the first, of which we are aware, to compartmentalise methanogenic granules into discrete, size-resolved fractions, which were then used to separately start up bioreactors to investigate the granule life cycle. The evidence, and extent, ofde novogranule growth, and the identification of key microorganisms shaping new granules at different life-cycle stages, is important for environmental engineering and microbial ecology.

7. Diversity converges during community assembly in methanogenic granules, suggesting a biofilm life-cycle

Author

Umer Zeeshan Ijaz, Isabelle Bourven, Cristina Morabito, Anna Christine Trego, Christopher Quince, Gavin Collins, Giles Guibaud, Stephanie Connelly, and Simon Mills

Subjects

chemistry.chemical_classification, biology, chemistry, Granule (cell biology), Niche, Biofilm, Organic matter, Microbiome, Food science, Euryarchaeota, biology.organism_classification, Anaerobic exercise, Bacteria

Abstract

Anaerobic biological decomposition of organic matter is ubiquitous in Nature wherever anaerobic environments prevail, and is catalysed by hydrolytic, fermentative, acetogenic, methanogenic, and various other groups, including syntrophic bacteria. It is also harnessed in innovative ways in engineered systems that may rely on small (0.1-4.0 mm), spherical, anaerobic granules, which we have found to be highly-replicated, whole-ecosystems harbouring the entire community necessary to mineralise complex organics. We hypothesised distinct granule sizes correspond to stages in a biofilm life-cycle, in which small granules are young and larger ones are old. Here, granules were separated into 10 size fractions used for physico-chemical and ecological characterisation. Gradients of volatile solids, density, settleability, biofilm morphology, methanogenic activity, and EPS profiles were observed across size fractions. Sequencing of 16S rRNA genes indicated linear convergence of diversity during community assembly as granules increased in size. A total of 155 discriminant OTUs were identified, and correlated strongly with physico-chemical parameters. Community assembly across sizes was influenced by a niche effect, whereby Euryarchaeota dominated a core microbiome presumably as granules became more anaerobic. The findings indicate opportunities for precision management of environmental biotechnologies, and the potential of aggregates as playgrounds to study assembly and succession in whole microbiomes.