Your search keyword '"Attwood, Graeme T."' showing total 6 results

1. Hydrogen and formate production and utilisation in the rumen and the human colon

Author

Kelly, William J., Mackie, Roderick I., Attwood, Graeme T., Janssen, Peter H., McAllister, Tim A., and Leahy, Sinead C.

Published

2022

2. The complete genome sequence of the methanogenic archaeon ISO4-H5 provides insights into the methylotrophic lifestyle of a ruminal representative of the Methanomassiliicoccales.

Author

Yang Li, Leahy, Sinead C., Jeyanathan, Jeyamalar, Henderson, Gemma, Cox, Faith, Altermann, Eric, Kelly, William J., Lambie, Suzanne C., Janssen, Peter H., Rakonjac, Jasna, and Attwood, Graeme T.

Subjects

NUCLEOTIDE sequencing, METHANOGENS, METHYLOTROPHIC microorganisms, PYRROLYSINE, COENZYME M, RUMINANTS

Abstract

Methane emissions from agriculture represent around 9% of global anthropogenic greenhouse emissions. The single largest source of this methane is animal enteric fermentation, predominantly from ruminant livestock where it is produced mainly in their fermentative forestomach (or reticulo-rumen) by a group of archaea known as methanogens. In order to reduce methane emissions from ruminants, it is necessary to understand the role of methanogenic archaea in the rumen, and to identify their distinguishing characteristics that can be used to develop methane mitigation technologies. To gain insights into the role of methylotrophic methanogens in the rumen environment, the genome of a methanogenic archaeon has been sequenced. This isolate, strain ISO4-H5, was isolated from the ovine rumen and belongs to the order Methanomassiliicoccales. Genomic analysis suggests ISO4-H5 is an obligate hydrogen-dependent methylotrophic methanogen, able to use methanol and methylamines as substrates for methanogenesis. Like other organisms within this order, ISO4-H5 does not possess genes required for the first six steps of hydrogenotrophic methanogenesis. Comparison between the genomes of different members of the order Methanomassiliicoccales revealed strong conservation in energy metabolism, particularly in genes of the methylotrophic methanogenesis pathway, as well as in the biosynthesis and use of pyrrolysine. Unlike members of Methanomassiliicoccales from human sources, ISO4-H5 does not contain the genes required for production of coenzyme M, and so likely requires external coenzyme M to survive. [ABSTRACT FROM AUTHOR]

Published

2016

3. An adhesin from hydrogen-utilizing rumen methanogen M ethanobrevibacter ruminantium M1 binds a broad range of hydrogen-producing microorganisms.

Author

Ng, Filomena, Kittelmann, Sandra, Patchett, Mark L., Attwood, Graeme T., Janssen, Peter H., Rakonjac, Jasna, and Gagic, Dragana

Subjects

METHANOGENS, BREVIBACTERIUM, HYDROGEN bacteria, BACTERIAL mutation, HYDROGEN transfer reactions

Abstract

Symbiotic associations are ubiquitous in the microbial world and have a major role in shaping the evolution of both partners. One of the most interesting mutualistic relationships exists between protozoa and methanogenic archaea in the fermentative forestomach (rumen) of ruminant animals. Methanogens reside within and on the surface of protozoa as symbionts, and interspecies hydrogen transfer is speculated to be the main driver for physical associations observed between the two groups. In silico analyses of several rumen methanogen genomes have previously shown that up to 5% of genes encode adhesin-like proteins, which may be central to rumen interspecies attachment. We hypothesized that adhesin-like proteins on methanogen cell surfaces facilitate attachment to protozoal hosts. Using phage display technology, we have identified a protein ( Mru_1499) from M ethanobrevibacter ruminantium M1 as an adhesin that binds to a broad range of rumen protozoa (including the genera E pidinium and E ntodinium). This unique adhesin also binds the cell surface of the bacterium B utyrivibrio proteoclasticus, suggesting a broad adhesion spectrum for this protein. [ABSTRACT FROM AUTHOR]

Published

2016

4. The complete genome sequence of the rumen methanogen Methanobrevibacter millerae SM9.

Author

Kelly, William J., Pacheco, Diana M., Dong Li, Attwood, Graeme T., Altermann, Eric, and Leahy, Sinead C.

Subjects

NUCLEOTIDE sequencing, METHANOGENS, RUMINANTS, NONRIBOSOMAL peptide synthetases, LACTOBACILLUS plantarum, COENZYMES

Abstract

Methanobrevibacter millerae SM9 was isolated from the rumen of a sheep maintained on a fresh forage diet, and its genome has been sequenced to provide information on the phylogenetic diversity of rumen methanogens with a view to developing technologies for methane mitigation. It is the first rumen isolate from the Methanobrevibacter gottschalkii clade to have its genome sequence completed. The 2.54 Mb SM9 chromosome has an average G + C content of 31.8%, encodes 2269 protein-coding genes, and harbors a single prophage. The overall gene content is comparable to that of Methanobrevibacter ruminantium M1 and the type strain of M. millerae (ZA-10T) suggesting that the basic metabolism of these two hydrogenotrophic rumen methanogen species is similar. However, M. millerae has a larger complement of genes involved in methanogenesis including genes for methyl coenzyme M reductase II (mrtAGDB) which are not found in M1. Unusual features of the M. millerae genomes include the presence of a tannase gene which shows high sequence similarity with the tannase from Lactobacillus plantarum, and large non-ribosomal peptide synthase genes. The M. millerae sequences indicate that methane mitigation strategies based on the M. ruminantium M1 genome sequence are also likely to be applicable to members of the M. gottschalkii clade. [ABSTRACT FROM AUTHOR]

Published

2016

5. Strategies to reduce methane emissions from farmed ruminants grazing on pasture.

Author

Buddle, Bryce M., Denis, Michel, Attwood, Graeme T., Altermann, Eric, Janssen, Peter H., Ronimus, Ron S., Pinares-Patiño, Cesar S., Muetzel, Stefan, and Wedlock, D. Neil

Subjects

*METHANE, *GRAZING, *PASTURES, *GREENHOUSE gas mitigation, *RUMINANTS

Abstract

Methane emissions from livestock are a significant contributor to greenhouse gas emissions and have become a focus of research activities, especially in countries where agriculture is a major economic sector. Understanding the complexity of the rumen microbiota, including methane-producing Archaea, is in its infancy. There are currently no robust, reproducible and economically viable methods for reducing methane emissions from ruminants grazing on pasture and novel innovative strategies to diminish methane output from livestock are required. In this review, current approaches towards mitigation of methane in pastoral farming are summarised. Research strategies based on vaccination, enzyme inhibitors, phage, homoacetogens, defaunation, feed supplements, and animal selection are reviewed. Many approaches are currently being investigated, and it is likely that more than one strategy will be required to enable pastoral farming to lower its emissions of methane significantly. Different strategies may be suitable for different farming practices and systems. [ABSTRACT FROM AUTHOR]

Published

2011

6. Sharpea and Kandleria are lactic acid producing rumen bacteria that do not change their fermentation products when co-cultured with a methanogen.

Author

Kumar, Sandeep, Treloar, Bryan P., Teh, Koon Hoong, McKenzie, Catherine M., Henderson, Gemma, Attwood, Graeme T., Waters, Sinéad M., Patchett, Mark L., and Janssen, Peter H.

Subjects

*LACTIC acid bacteria, *RUMEN fermentation, *LACTATES, *HYDROGEN, *METHANOGENS

Abstract

Abstract Sharpea and Kandleria are associated with rumen samples from low-methane-emitting sheep. Four strains of each genus were studied in culture, and the genomes of nine strains were analysed, to understand the physiology of these bacteria. All eight cultures grew equally well with d -glucose, d -fructose, d -galactose, cellobiose, and sucrose supplementation. d -Lactate was the major end product, with small amounts of the mixed acid fermentation products formate, acetate and ethanol. Genes encoding the enzymes necessary for this fermentation pattern were found in the genomes of four strains of Sharpea and five of Kandleria. Strains of Sharpea produced traces of hydrogen gas in pure culture, but strains of Kandleria did not. This was consistent with finding that Sharpea , but not Kandleria , genomes contained genes coding for hydrogenases. It was speculated that, in co-culture with a methanogen, Sharpea and Kandleria might change their fermentation pattern from a predominately homolactic to a predominately mixed acid fermentation, which would result in a decrease in lactate production and an increase in formation of acetate and perhaps ethanol. However, Sharpea and Kandleria did not change their fermentation products when co-cultured with Methanobrevibacter olleyae , a methanogen that can use both hydrogen and formate, and lactate remained the major end product. The results of this study therefore support a hypothesis that explains the link between lower methane yields and larger populations of Sharpea and Kandleria in the rumens of sheep. Highlights • Sharpea and Kandleria produce mainly lactate, and some acetate, ethanol and formate. • Genome analysis found all genes needed for the products detected in culture studies. • Products were unchanged in co-cultures with a hydrogen and formate-using methanogen. • This supports a previous hypothesis explaining low methane emissions by sheep. [ABSTRACT FROM AUTHOR]

Published

2018