Identification, Comparison, and Validation of Robust Rumen Microbial Biomarkers for Methane Emissions Using Diverse Bos Taurus Breeds and Basal Diets

Auffret, Marc; Stewart, Robert D.; Dewhurst, Richard J.; Duthie, Carol-Anne; Rooke, J. A.; Wallace, Robert John; Freeman, Thomas Charles Augustus; Snelling, Timothy J.; Watson, Michael; Roehe, R.

doi:10.3389/fmicb.2017.02642

Cited by 72 publications

(82 citation statements)

References 66 publications

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“…Overall, what can be noted from the literature is that when trying to predict CH 4 emissions with metabolite-based models, goodness of fit as measured by the R 2 coefficient is generally between 0.3-0.5. Therefore, comparing our current results with these studies, even if comparison based on the R 2 measure only is a notable simplification as it depends on technical details of the modeling used and particuliarities of the data in each study, we find that they are in line with previous work 11,14,44,45 , although ours were derived from solely utilising NMR metabolic profiles as predictors. It should also be noted that, similarly to the studies mentioned above, predictive abilities improved following addition of both animal and diet covariates (R 2 = 0.70), reinforcing the evidence that these factors are still the main influencers on CH 4 emissions.…”

Section: Discussionsupporting

confidence: 85%

“…Studies have been undertaken to try and model different variables which might be correlated to CH 4 emissions with varying results. Auffret et al 14 aimed to identify robust microbial biomarkers which could be used to predict CH 4 emissions. By applying a simple regression analysis they identified the archaea:bacteria ratio as a biomarker for methane emissions, and a PLS analysis (which included 56 genera, diet effects and breed types) explained 50% of variation in methane yield.…”

Section: Discussionmentioning

confidence: 99%

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Nuclear Magnetic Resonance to Detect Rumen Metabolites Associated with Enteric Methane Emissions from Beef Cattle

Bica

Palarea‐Albaladejo

Kew

et al. 2020

Sci Rep

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this study presents the application of metabolomics to evaluate changes in the rumen metabolites of beef cattle fed with three different diet types: forage-rich, mixed and concentrate-rich. Rumen fluid samples were analysed by 1 H-nMR spectroscopy and the resulting spectra were used to characterise and compare metabolomic profiles between diet types and assess the potential for NMR metabolite signals to be used as proxies of methane emissions (CH 4 in g/kg DMi). the dataset available consisted of 128 measurements taken from 4 experiments with CH 4 measurements taken in respiration chambers. predictive modelling of cH 4 was conducted by partial least squares (PLS) regression, fitting calibration models either using metabolite signals only as predictors or using metabolite signals as well as other diet and animal covariates (DMI, ME, weight, BW 0.75 , DMI/BW 0.75). cross-validated R 2 were 0.57 and 0.70 for the two models respectively. The cattle offered the concentrate-rich diet showed increases in alanine, valerate, propionate, glucose, tyrosine, proline and isoleucine. Lower methane yield was associated with the concentrate-rich diet (p < 0.001). The results provided new insight into the relationship between rumen metabolites, CH 4 production and diets, as well as showing that metabolites alone have an acceptable association with the variation in cH 4 production from beef cattle. Livestock production is the largest anthropogenic contributor to the global CH 4 budget (103 [95-109] Tg CH 4 yr−1 during 2000-2009) 1 , with enteric CH 4 emissions being the largest contributors to this (87-97 Tg CH 4 yr−1 during 2000-2009) 1-3. Methane is a potent greenhouse gas (GHG) with a global warming potential (GWP) 28 times higher than carbon dioxide (CO 2), with a 12-year atmospheric lifetime 4 and it contributes significantly to stratospheric ozone depletion 5. Methane production is also associated with a net loss of energy to the animal, ranging from 2-12% of energy intake 6. Methane production is mainly associated with fermentation of feed and occurs primarily in the rumen, with the rest (11% in one study) occurring in the lower hindgut 7. Rumen methanogens principally utilise H 2 and CO 2 to produce CH 4 in the hydrogenotrophic pathway. Acetate and butyrate production results in more H 2 being produced and available for CH 4 production, whilst propionate results in less, as propionate production uses up H 2 , leaving less available for CH 4 production 8,9. Until recently, this was thought to be the sole pathway for CH 4 production. However, another group of methanogens uses methyl-containing metabolites such as methanol and methylamine to produce CH 4 , utilising the methylotrophic methanogenic pathway 10. This pathway is found in the Thermoplasmata genus of archaea showing enhanced growth when given methylamine supplements. The contribution of these substrates to CH 4 production has not been assessed as yet, although it is known that these archaea can be stimulated by increasing dietary pectin concentrations, as well as i...

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Section: Discussionsupporting

confidence: 85%

Section: Discussionmentioning

confidence: 99%

Nuclear Magnetic Resonance to Detect Rumen Metabolites Associated with Enteric Methane Emissions from Beef Cattle

Bica

Palarea‐Albaladejo

Kew

et al. 2020

Sci Rep

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show abstract

“…Several authors have succeeded in using information about microbial communities or microbial genes to predict CH 4 emissions (Roehe et al, 2016;Shabat et al, 2016;Auffret et al, 2018;Difford et al, 2018) but restricted to archaea and bacteria communities. However, in order to develop efficient CH 4 mitigation strategies using microbiome information, we need improved knowledge about the rumen microbiome.…”

Section: Introductionmentioning

confidence: 99%

“…Coabundance patterns between microbials have been previously used as a prediction of microbial interactions (Faust and Raes, 2012). Network-based analytical approaches have helped disentangle complex polymicrobial and microbehost interactions in ruminants, humans and soil (Barberán et al, 2012;Roehe et al, 2016;Sung et al, 2017;Auffret et al, 2018) by identifying patterns of microbial interactions in ecosystems occupied by highly diverse microorganisms. Within a network, several clusters considered as a single biological unit may provide information about the local interaction patterns, the biological contribution of each cluster and therefore its function in the microbiome (reviewed in Faust and Raes, 2012).…”

Section: Introductionmentioning

confidence: 99%

Identification of Complex Rumen Microbiome Interaction Within Diverse Functional Niches as Mechanisms Affecting the Variation of Methane Emissions in Bovine

et al. 2020

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Martínez-Álvaro et al. Microbiome Network Explains Methane Emissions lactate and succinate and synthesis of more complex amino acids by γ-Proteobacteria. When analyzing low-and high-methane emitters data in separate networks, competition between methanogens in the methanogenesis cluster was uncovered by a broader diversity of methanogens involved in the three methanogenesis pathways and larger interactions within and between communities in low compared to high emitters. Generally, our results suggest that differences in CH 4 are mainly explained by other microbial communities and their activities rather than being only methanogens-driven. Our study provides insight into the interactions of the rumen microbial communities and their genes by uncovering functional niches affecting CH 4 , which will benefit the development of efficient CH 4 mitigation strategies.

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“…This production represents a loss of energy and carbon for the animal, estimated to be between 2 and 12% 6 . Methane production has been directly linked to the abundance of methanogenic archaea in the rumen 7,8 , and is also under the control of rumen microbial metabolism thermodynamically dependent of hydrogen partial pressure 9 . Moreover, it is been shown to be under the influence of host genetics 10 , offering possibilities for mitigating this issue through selection or manipulation of the microbiome.…”

Section: Introductionmentioning

confidence: 99%

The genomic and proteomic landscape of the rumen microbiome revealed by comprehensive genome-resolved metagenomics

Stewart¹,

Auffret²,

Warr³

et al. 2018

Preprint

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Ruminants provide essential nutrition for billions of people worldwide. The rumen is a specialised stomach adapted to the breakdown of plant-derived complex polysaccharides, and collectively the rumen microbiota encode the thousands of enzymes responsible. Here we present a comprehensive analysis of over 6.5 terabytes of Illumina and Nanopore sequence data, including assembly of 4941 metagenome-assembled genomes, and several single-contig, whole-chromosome assemblies of novel rumen bacteria. We also present the largest dataset of predicted proteins from the rumen, and provide rich annotation against public datasets. Together these data will form an essential part of future studies of rumen microbiome structure and function.

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Identification, Comparison, and Validation of Robust Rumen Microbial Biomarkers for Methane Emissions Using Diverse Bos Taurus Breeds and Basal Diets

Cited by 72 publications

References 66 publications

Nuclear Magnetic Resonance to Detect Rumen Metabolites Associated with Enteric Methane Emissions from Beef Cattle

Nuclear Magnetic Resonance to Detect Rumen Metabolites Associated with Enteric Methane Emissions from Beef Cattle

Identification of Complex Rumen Microbiome Interaction Within Diverse Functional Niches as Mechanisms Affecting the Variation of Methane Emissions in Bovine

The genomic and proteomic landscape of the rumen microbiome revealed by comprehensive genome-resolved metagenomics

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