Your search keyword '"Creevey CJ"' showing total 5 results

1. Microbiomes attached to fresh perennial ryegrass are temporally resilient and adapt to changing ecological niches.

Author

Huws SA, Edwards JE, Lin W, Rubino F, Alston M, Swarbreck D, Caim S, Stevens PR, Pachebat J, Won MY, Oyama LB, Creevey CJ, and Kingston-Smith AH

Subjects

Animals, Humans, Plant Breeding, Rumen, Gastrointestinal Microbiome genetics, Lolium, Microbiota genetics

Abstract

Background: Gut microbiomes, such as the rumen, greatly influence host nutrition due to their feed energy-harvesting capacity. We investigated temporal ecological interactions facilitating energy harvesting at the fresh perennial ryegrass (PRG)-biofilm interface in the rumen using an in sacco approach and prokaryotic metatranscriptomic profiling., Results: Network analysis identified two distinct sub-microbiomes primarily representing primary (≤ 4 h) and secondary (≥ 4 h) colonisation phases and the most transcriptionally active bacterial families (i.e Fibrobacteriaceae, Selemondaceae and Methanobacteriaceae) did not interact with either sub-microbiome, indicating non-cooperative behaviour. Conversely, Prevotellaceae had most transcriptional activity within the primary sub-microbiome (focussed on protein metabolism) and Lachnospiraceae within the secondary sub-microbiome (focussed on carbohydrate degradation). Putative keystone taxa, with low transcriptional activity, were identified within both sub-microbiomes, highlighting the important synergistic role of minor bacterial families; however, we hypothesise that they may be 'cheating' in order to capitalise on the energy-harvesting capacity of other microbes. In terms of chemical cues underlying transition from primary to secondary colonisation phases, we suggest that AI-2-based quorum sensing plays a role, based on LuxS gene expression data, coupled with changes in PRG chemistry., Conclusions: In summary, we show that fresh PRG-attached prokaryotes are resilient and adapt quickly to changing niches. This study provides the first major insight into the complex temporal ecological interactions occurring at the plant-biofilm interface within the rumen. The study also provides valuable insights into potential plant breeding strategies for development of the utopian plant, allowing optimal sustainable production of ruminants. Video Abstract.

Published

2021

2. Improvement of Feed Efficiency in Pigs through Microbial Modulation via Fecal Microbiota Transplantation in Sows and Dietary Supplementation of Inulin in Offspring.

Author

McCormack UM, Curião T, Metzler-Zebeli BU, Wilkinson T, Reyer H, Crispie F, Cotter PD, Creevey CJ, Gardiner GE, and Lawlor PG

Subjects

Animal Feed analysis, Animals, Bacteria classification, Bacteria isolation & purification, Energy Metabolism, Feces microbiology, Female, Pregnancy, Swine growth & development, Weaning, Body Weight, Dietary Supplements, Fecal Microbiota Transplantation veterinary, Gastrointestinal Microbiome, Inulin administration & dosage

Abstract

As previous studies have demonstrated a link between the porcine intestinal microbiome and feed efficiency (FE), microbiota manipulation may offer a means of improving FE in pigs. A fecal microbiota transplantation procedure (FMTp), using fecal extracts from highly feed-efficient pigs, was performed in pregnant sows ( n  = 11), with a control group ( n  = 11) receiving no FMTp. At weaning, offspring were allocated, within sow treatment, to (i) control ( n  = 67; no dietary supplement) or (ii) inulin ( n  = 65; 6-week dietary inulin supplementation) treatments. The sow FMTp, alone or in combination with inulin supplementation in offspring, reduced offspring body weight by 8.1 to 10.6 kg at ∼140 days of age, but there was no effect on feed intake. It resulted in better FE, greater bacterial diversity, and higher relative abundances of potentially beneficial bacterial taxa ( Fibrobacter and Prevotella ) in offspring. Due to the FMTp and/or inulin supplementation, relative abundances of potential pathogens ( Chlamydia and Treponema ) in the ileum and cecal concentrations of butyric acid were significantly lower. The maternal FMTp led to a greater number of jejunal goblet cells in offspring. Inulin supplementation alone did not affect growth or FE but upregulated duodenal genes linked to glucose and volatile fatty acid homeostasis and increased the mean platelet volume but reduced ileal propionic acid concentrations, granulocyte counts, and serum urea concentrations. Overall, the FMTp in pregnant sows, with or without dietary inulin supplementation in offspring, beneficially modulated offspring intestinal microbiota (albeit mostly low-relative-abundance taxa) and associated physiological parameters. Although FE was improved, the detrimental effect on growth limits the application of this FMTp-inulin strategy in commercial pig production. IMPORTANCE As previous research suggests a link between microbiota and FE, modulation of the intestinal microbiome may be effective in improving FE in pigs. The FMTp in gestating sows, alone or in combination with postweaning dietary inulin supplementation in offspring, achieved improvements in FE and resulted in a higher relative abundance of intestinal bacteria associated with fiber degradation and a lower relative abundance of potential pathogens. However, there was a detrimental effect on growth, although this may not be wholly attributable to microbiota transplantation, as antibiotic and other interventions were also part of the FMT regimen. Therefore, further work with additional control groups is needed to disentangle the effects of each component of the FMTp in order to develop a regimen with practical applications in pig production. Additional research based on findings from this study may also identify specific dietary supplements for the promotion/maintenance of the microbiota transferred via the maternal FMTp, thereby optimizing pig growth and FE., (Copyright © 2019 American Society for Microbiology.)

Published

2019

3. Meta-proteomics of rumen microbiota indicates niche compartmentalisation and functional dominance in a limited number of metabolic pathways between abundant bacteria.

Author

Hart EH, Creevey CJ, Hitch T, and Kingston-Smith AH

Subjects

Animal Feed, Animals, Bacteria genetics, Bacteria isolation & purification, Cattle, DNA, Bacterial isolation & purification, Female, Fermentation physiology, Gene Expression Profiling, Metabolic Networks and Pathways physiology, Proteomics methods, RNA, Ribosomal, 16S genetics, Bacteria metabolism, Bacterial Proteins metabolism, Gastrointestinal Microbiome physiology, Proteome metabolism, Rumen microbiology

Abstract

The rumen is a complex ecosystem. It is the primary site for microbial fermentation of ingested feed allowing conversion of a low nutritional feed source into high quality meat and milk products. However, digestive inefficiencies lead to production of high amounts of environmental pollutants; methane and nitrogenous waste. These inefficiencies could be overcome by development of forages which better match the requirements of the rumen microbial population. Although challenging, the application of meta-proteomics has potential for a more complete understanding of the rumen ecosystem than sequencing approaches alone. Here, we have implemented a meta-proteomic approach to determine the association between taxonomies of microbial sources of the most abundant proteins in the rumens of forage-fed dairy cows, with taxonomic abundances typical of those previously described by metagenomics. Reproducible proteome profiles were generated from rumen samples. The most highly abundant taxonomic phyla in the proteome were Bacteriodetes, Firmicutes and Proteobacteria, which corresponded with the most abundant taxonomic phyla determined from 16S rRNA studies. Meta-proteome data indicated differentiation between metabolic pathways of the most abundant phyla, which is in agreement with the concept of diversified niches within the rumen microbiota.

Published

2018

4. Cultivation and sequencing of rumen microbiome members from the Hungate1000 Collection.

Author

Seshadri R, Leahy SC, Attwood GT, Teh KH, Lambie SC, Cookson AL, Eloe-Fadrosh EA, Pavlopoulos GA, Hadjithomas M, Varghese NJ, Paez-Espino D, Perry R, Henderson G, Creevey CJ, Terrapon N, Lapebie P, Drula E, Lombard V, Rubin E, Kyrpides NC, Henrissat B, Woyke T, Ivanova NN, and Kelly WJ

Subjects

Animals, Archaea classification, Archaea metabolism, Bacteria classification, Bacteria metabolism, Biofuels, Humans, Lignin chemistry, Lignin genetics, Microbiota genetics, Archaea genetics, Bacteria genetics, Gastrointestinal Microbiome genetics, Rumen microbiology

Abstract

Productivity of ruminant livestock depends on the rumen microbiota, which ferment indigestible plant polysaccharides into nutrients used for growth. Understanding the functions carried out by the rumen microbiota is important for reducing greenhouse gas production by ruminants and for developing biofuels from lignocellulose. We present 410 cultured bacteria and archaea, together with their reference genomes, representing every cultivated rumen-associated archaeal and bacterial family. We evaluate polysaccharide degradation, short-chain fatty acid production and methanogenesis pathways, and assign specific taxa to functions. A total of 336 organisms were present in available rumen metagenomic data sets, and 134 were present in human gut microbiome data sets. Comparison with the human microbiome revealed rumen-specific enrichment for genes encoding de novo synthesis of vitamin B 12 , ongoing evolution by gene loss and potential vertical inheritance of the rumen microbiome based on underrepresentation of markers of environmental stress. We estimate that our Hungate genome resource represents ∼75% of the genus-level bacterial and archaeal taxa present in the rumen.

Published

2018

5. Temporal dynamics of the metabolically active rumen bacteria colonizing fresh perennial ryegrass.

Author

Huws SA, Edwards JE, Creevey CJ, Rees Stevens P, Lin W, Girdwood SE, Pachebat JA, and Kingston-Smith AH

Subjects

Actinobacteria genetics, Actinobacteria isolation & purification, Actinobacteria metabolism, Animals, Bacteria genetics, Bacteria isolation & purification, Butyrivibrio genetics, Butyrivibrio isolation & purification, Butyrivibrio metabolism, Cattle, Female, Fibrobacter genetics, Fibrobacter isolation & purification, Fibrobacter metabolism, Gastrointestinal Microbiome physiology, Prevotella genetics, Prevotella isolation & purification, Prevotella metabolism, RNA, Ribosomal, 16S genetics, Ruminococcus genetics, Ruminococcus isolation & purification, Ruminococcus metabolism, Succinivibrionaceae genetics, Succinivibrionaceae isolation & purification, Succinivibrionaceae metabolism, Bacteria metabolism, Gastrointestinal Microbiome genetics, Lolium microbiology, Rumen microbiology

Abstract

This study investigated successional colonization of fresh perennial ryegrass (PRG) by the rumen microbiota over time. Fresh PRG was incubated in sacco in the rumens of three Holstein × Friesian cows over a period of 8 h, with samples recovered at various times. The diversity of attached bacteria was assessed using 454 pyrosequencing of 16S rRNA (cDNA). Results showed that plant epiphytic communities either decreased to low relative abundances or disappeared following rumen incubation, and that temporal colonization of the PRG by the rumen bacteria was biphasic with primary (1 and 2 h) and secondary (4-8 h) events evident with the transition period being with 2-4 h. A decrease in sequence reads pertaining to Succinivibrio spp. and increases in Pseudobutyrivibrio, Roseburia and Ruminococcus spp. (the latter all order Clostridiales) were evident during secondary colonization. Irrespective of temporal changes, the continually high abundances of Butyrivibrio, Fibrobacter, Olsenella and Prevotella suggest that they play a major role in the degradation of the plant. It is clear that a temporal understanding of the functional roles of these microbiota within the rumen is now required to unravel the role of these bacteria in the ruminal degradation of fresh PRG., (© FEMS 2015. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2016