Genomewide association study of methane emissions in Angus beef cattle with validation in dairy cattle1

Manzanilla-Pech, C.I.V.; Haas, Y. de; Hayes, Ben J.; Veerkamp, R.F.; Khansefid, Majid; Donoghue, K. A.; Arthur, P. F.; Pryce, J.E.

doi:10.2527/jas.2016-0431

Cited by 46 publications

(59 citation statements)

References 41 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Another option, then, is to look at methane intensity, defined as liters of CH 4 related to output [e.g., kg milk (for dairy) or meat (for sheep or beef) produced], or at methane yield, defined as liters of CH 4 related to input (e.g., per kg of DMI). Residual methane production, defined as observed minus predicted CH 4 production, has also been suggested for use (Herd et al, 2014;Berry et al, 2015;Manzanilla Pech et al, 2016). Residual methane production is based on the same concept as residual feed intake (RFI), where the phenotype of interest is regressed for each factor that influences this phenotype.…”

Section: Possible Direct Phenotypesmentioning

confidence: 99%

Invited review: Phenotypes to genetically reduce greenhouse gas emissions in dairying

Haas

Pszczoła

Soyeurt

et al. 2017

Journal of Dairy Science

Self Cite

View full text Add to dashboard Cite

Phenotypes have been reviewed to select for loweremitting animals in order to decrease the environmental footprint of dairy cattle products. This includes direct selection for breath measurements, as well as indirect selection via indicator traits such as feed intake, milk spectral data, and rumen microbial communities. Many of these traits are expensive or difficult to record, or both, but with genomic selection, inclusion of methane emission as a breeding goal trait is feasible, even with a limited number of registrations. At present, methane emission is not included among breeding goals for dairy cattle worldwide. There is no incentive to include enteric methane in breeding goals, although global warming and the release of greenhouse gases is a much-debated political topic. However, if selection for reduced methane emission became a reality, there would be limited consensus as to which phenotype to select for: methane in liters per day or grams per day, methane in liters per kilogram of energy-corrected milk or dry matter intake, or a residual methane phenotype, where methane production is corrected for milk production and the weight of the cow. We have reviewed the advantages and disadvantages of these traits, and discuss the methods for selection and consequences for these phenotypes.

show abstract

Section: Possible Direct Phenotypesmentioning

confidence: 99%

Invited review: Phenotypes to genetically reduce greenhouse gas emissions in dairying

Haas

Pszczoła

Soyeurt

et al. 2017

Journal of Dairy Science

Self Cite

View full text Add to dashboard Cite

show abstract

“…De Haas et al [7] reported that the estimated heritability of predicted methane emission (PME) per milk production and PME per milk production corrected for fat and protein content were 0.35 and 0.58, respectively. Moreover, genome-wide association studies (GWAS) have identified several single nucleotide polymorphisms (SNPs) associated with the measured or predicted rate of methane emission in Holstein cattle [7] and Angus cattle [8]. Thus, genetic selection can be employed to reduce PME per unit of milk production.…”

Section: Introductionmentioning

confidence: 99%

“…Cattle have a considerable ability to produce high-quality proteins from non-edible plant cell wall components for human consumption [16]. However, it is well established that gastrointestinal microbiota contributes to feed digestion and enteric methane emission in ruminants [17][18][19][20], as approximately 17% of global methane emissions generated through ruminants [8]. Methane emission is a difficult and expensive trait to measure and is not routinely measured in dairy cattle.…”

mentioning

confidence: 99%

“…However, they reported that seven SNPs associated with PME in Holstein cattle could explain only 0.2% of the total genetic variance [7]. In another GWAS, 3,304 significant SNPs were identified for PME (p < 0.005) in which 630 of them were also associated with weight-at-test and dry-matter intake [8]. It has been estimated that 19% to 23% of methane emissions per kg of milk can be reduced and converted to production when cows are selected based on milk fat plus protein (19%), or based on the average genetic merit of milk fat plus protein yield (23%) [22].…”

mentioning

confidence: 99%

See 1 more Smart Citation

Genome-wide association studies for methane emission and ruminal volatile fatty acids using Holstein cattle sequence data

Sarghale

Shahrebabak

et al. 2020

Preprint

View full text Add to dashboard Cite

Background: Methane emission by ruminants has contributed considerably to the global warming and understanding the genomic architecture of methane production may help the livestock producers to reduce the methane emission from the livestock production system. The goal of our study was to identify genomic regions affecting the predicted methane emission (PME) from volatile fatty acids (VFAs) indicators and VFA traits using imputed whole-genome sequence data in Iranian Holstein cattle. Results: Based on the significant-association threshold ( p < 5 × 10 −8 ), 33 single nucleotide polymorphisms (SNPs) were detected for PME per kg milk (n=2), PME per kg fat (n=14), and valeric acid (n=17). Besides, 69 genes were identified for valeric acid (n=18), PME per kg milk (n=4) and PME per kg fat (n=47) that were located within 1 Mb of significant SNPs. Based on the gene ontology (GO) term analysis, six promising candidate genes were significantly clustered in organelle organization (GO:0004984, p = 3.9 × 10 -2 ) for valeric acid, and 17 candidate genes significantly clustered in olfactory receptors activity (GO:0004984, p = 4 × 10 -10 ) for PME traits. Annotation results revealed 31 quantitative trait loci (QTLs) for milk yield and its components, body weight, and residual feed intake within 1 Mb of significant SNPs. Conclusions: Our results identified 33 SNPs associated with PME and valeric acid traits, as well as 17 olfactory receptors activity genes for PME traits related to food preference and feed intake. Identified SNPs in this study were close to 31 QTLs for milk yield and its components, body weight, and residual feed intake traits. In addition, these traits had high correlations with PME trait. Overall, our findings suggest that marker-assisted and genomic selection could be used to improve the difficult and expensive-to-measure phenotypes such as PME. Moreover, prediction of methane emission by VFA indicators could be useful for increasing the size of the reference population required in genome-wide association studies and genomic selection.

show abstract

“…The genetic background of CH4 emission has been studied before in beef and dairy cattle Manzanilla-Pech et al, 2016). No specific regions of the genome were found to be significantly associated in the GWAS on CH4 emission predicted with feed intake in 665 dairy cows .…”

Section: Genetic Background Of Ch4 Emissionmentioning

confidence: 99%

The genetic background of methane emission by dairy cows

Engelen¹

View full text Add to dashboard Cite

Van Engelen, S. (2018). The genetic background of methane emission by dairy cows. PhD thesis, Wageningen University, the Netherlands Dairy products are important food sources which contain nutrients that are essential for human development and healthy ageing. Greenhouse gasses are formed during the production of dairy of which methane (CH4) emission by dairy cows is the single largest source. A reduction in CH4 emission could be achieved via selective breeding, though this requires genetic variation in CH4 emission. In order to quantify the genetic variation in CH4 emission, 3 different indicators were used. The first indicator was CH4 emission predicted based on milk fatty acids (FA) which were measured using gas chromatography. Different FA based CH4 prediction equations were used and 12 to 44% of the variation was due to genetic differences between cows. The second indicator was CH4 emission measured with breath sensors. The breath of cows was analysed during milking in automatic milking systems. Genetics explained 3 to 12% of the total variation in this CH4 indicator. The third indicator was CH4 emission predicted based on milk mid-infrared (MIR) spectra. Of this indicator, between 17 and 21% of the total variation could be attributed to genetic factors. These results suggest that there is genetic variation in CH4 emission and selective breeding for lower CH4 emission is possible. The correlations between sensor measured CH4 emission and milk MIR predicted CH4 emission were low, indicating that both indicators explain a different part of the variation in true CH4 emission. The accuracy of the estimated breeding values (EBV) of these CH4 indicators confirms this suggestion. Combining information from sensor measured CH4 emission with milk MIR predicted CH4 emission increases the accuracy of the EBV compared to using them separately. Correlations of sensor measured CH4 emission and milk MIR predicted CH4 emission with breeding goal traits (production and fertility traits) were low to medium. Genetic correlations between CH4 emission and production traits ranged between-0.61 and 0.65, and genetic correlations between CH4 emission and fertility traits ranged between-0.32 and 0.38. These results suggest that inclusion of CH4 emission in the breeding goal has a minor impact on the breeding goal traits studied. These correlations, however, are estimated on relatively small datasets. Increasing the amount of data by using EBV, correlations between the EBV of the CH4 indicators and the EBV of six breeding goal traits were also low to medium. In conclusion, there is a possibility to use selective breeding to reduce CH4 emission by dairy cows with an anticipated minor impact on other breeding goal traits. "Nothing is as powerful as an idea whose time has come All my life, I've had doubts about who I am, where I belonged Now, I'm like the arrow that springs from the bow No hesitation, no doubts The path is clear"

show abstract

Genomewide association study of methane emissions in Angus beef cattle with validation in dairy cattle1

Cited by 46 publications

References 41 publications

Invited review: Phenotypes to genetically reduce greenhouse gas emissions in dairying

Invited review: Phenotypes to genetically reduce greenhouse gas emissions in dairying

Genome-wide association studies for methane emission and ruminal volatile fatty acids using Holstein cattle sequence data

The genetic background of methane emission by dairy cows

Contact Info

Product

Resources

About