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Review: Fifty years of research on rumen methanogenesis: lessons learned and future challenges for mitigation

Published online by Cambridge University Press:  06 February 2020

K. A. Beauchemin*
Affiliation:
Lethbridge Research and Development Centre, Agriculture and Agri-Food Canada, 5403 1st Avenue South, Lethbridge, Alberta, Canada, T1J 4B1
E. M. Ungerfeld
Affiliation:
Instituto de Investigaciones Agropecuarias INIA, Camino Cajón a Vilcún s/n km 10, Temuco, Chile
R. J. Eckard
Affiliation:
Faculty of Veterinary and Agricultural Sciences, University of Melbourne, Melbourne, VIC3010, Australia
M. Wang
Affiliation:
CAS Key Laboratory for Agro-Ecological Processes in Subtropical Region, National Engineering Laboratory for Pollution Control and Waste Utilization in Livestock and Poultry Production, Institute of Subtropical Agriculture, Chinese Academy of Sciences, Changsha, Hunan410125, P. R. China

Abstract

Meat and milk from ruminants provide an important source of protein and other nutrients for human consumption. Although ruminants have a unique advantage of being able to consume forages and graze lands not suitable for arable cropping, 2% to 12% of the gross energy consumed is converted to enteric CH4 during ruminal digestion, which contributes approximately 6% of global anthropogenic greenhouse gas emissions. Thus, ruminant producers need to find cost-effective ways to reduce emissions while meeting consumer demand for food. This paper provides a critical review of the substantial amount of ruminant CH4-related research published in past decades, highlighting hydrogen flow in the rumen, the microbiome associated with methanogenesis, current and future prospects for CH4 mitigation and insights into future challenges for science, governments, farmers and associated industries. Methane emission intensity, measured as emissions per unit of meat and milk, has continuously declined over the past decades due to improvements in production efficiency and animal performance, and this trend is expected to continue. However, continued decline in emission intensity will likely be insufficient to offset the rising emissions from increasing demand for animal protein. Thus, decreases in both emission intensity (g CH4/animal product) and absolute emissions (g CH4/day) are needed if the ruminant industries continue to grow. Providing producers with cost-effective options for decreasing CH4 emissions is therefore imperative, yet few cost-effective approaches are currently available. Future abatement may be achieved through animal genetics, vaccine development, early life programming, diet formulation, use of alternative hydrogen sinks, chemical inhibitors and fermentation modifiers. Individually, these strategies are expected to have moderate effects (<20% decrease), with the exception of the experimental inhibitor 3-nitrooxypropanol for which decreases in CH4 have consistently been greater (20% to 40% decrease). Therefore, it will be necessary to combine strategies to attain the sizable reduction in CH4 needed, but further research is required to determine whether combining anti-methanogenic strategies will have consistent additive effects. It is also not clear whether a decrease in CH4 production leads to consistent improved animal performance, information that will be necessary for adoption by producers. Major constraints for decreasing global enteric CH4 emissions from ruminants are continued expansion of the industry, the cost of mitigation, the difficulty of applying mitigation strategies to grazing ruminants, the inconsistent effects on animal performance and the paucity of information on animal health, reproduction, product quality, cost-benefit, safety and consumer acceptance.

Type
Review Article
Copyright
© Her Majesty the Queen in Right of Canada, as represented by the Minister of Agriculture and Agri-Food Canada 2020

Implications

Enteric CH4 from ruminants contributes approximately 6% of global anthropogenic greenhouse gas emissions. Thus, producers need cost-effective ways to lower emissions while meeting consumer demand for high-quality, safe and affordable food produced from healthy animals. Methane emissions per unit of meat and milk have continuously declined over the past decades due to improvements in production efficiency and animal performance. However, decreases in both intensity and absolute emissions of CH4 are needed to curb rising atmospheric greenhouse gas concentrations. The paper reviews future prospects for enteric CH4 mitigation and provides a critical analysis of the knowledge gaps and future challenges for science, governments, producers and livestock industries.

Introduction

Global demand for meat and milk is expected to increase by 73% and 58%, respectively, by 2050 compared with 2010 levels, due to continuous expansion of the world population, an emerging middle class, growing incomes and urbanization (Gerber et al., Reference Gerber, Steinfeld, Henderson, Mottet, Opio, Dijkman, Falcucci and Tempio2013). Expansion of animal agriculture is a concern because it contributes to rising atmospheric concentrations of greenhouse gases (GHGs) and consequent climate change. Total global GHG emissions from livestock (animals, manure, feed production and expansion of lands into forested areas) are estimated to account for 14.5% of total anthropogenic emissions (Gerber et al., Reference Gerber, Steinfeld, Henderson, Mottet, Opio, Dijkman, Falcucci and Tempio2013). Enteric CH4 from ruminants contributes approximately 6% of global anthropogenic GHG emissions (40% of all livestock emissions; Gerber et al., Reference Gerber, Steinfeld, Henderson, Mottet, Opio, Dijkman, Falcucci and Tempio2013). Methane has a much shorter lifetime (half-life; 8.6 years; Muller and Muller, Reference Muller and Muller2017) than CO2 in the atmosphere, which makes it an attractive amelioration target for short-term gains in global warming abatement.

Rising environmental awareness and vegetarianism, coupled with the emergence of synthetic milk and meat and limited resources, are challenging the ruminant livestock industries’ social licence to operate. Thus, it is imperative that ruminant producers develop cost-effective ways to continue decreasing CH4 emissions while meeting consumer demand for food. The GHG emissions per unit of meat and milk (also called carbon footprint and emission intensity) have declined over the past 50 years due to improvements in production efficiency and animal performance, and this trend is expected to continue, especially in countries with developing economies. However, the decline in emission intensity due to production efficiency gains is modest (<1%/year) and may be insufficient to offset the rising emissions from increasing demand for animal protein. Thus, a global concerted effort to reduce ruminant emissions is warranted.

Concern that enteric CH4 from ruminants is contributing to anthropogenic GHG emissions has promoted a recent research focus on understanding the factors affecting methanogenesis in the rumen, as well as exploration of a broad range of potential mitigation strategies. Consequently, a plethora of CH4-related papers has been published ranging from genome sequencing of rumen methanogens (Henderson et al., Reference Henderson, Cox, Ganesh, Jonker, Young and Janssen2015 and Reference Henderson, Cook and Ronimus2018; Seshadri et al., Reference Seshadri, Leahy, Attwood, Teh, Lambie, Cookson, Eloe-Fadrosh, Pavlopoulos, Hadjithomas, Varghese, Paez-Espino, Perry, Henderson, Creevey, Terrapon, Lapebie, Drula, Lombard, Rubin, Kyrpides, Henrissat, Woyke, Ivanova and Kelly2018) to practices that can be adopted to mitigate emissions (Beauchemin et al., Reference Beauchemin, McAllister and McGinn2009; Hristov et al., Reference Hristov, Oh, Lee, Meinen, Montes, Ott, Firkins, Rotz, Dell, Adesogan, Yang, Tricarico, Kebreab, Waghorn, Dijkstra, Oosting, Gerber, Henderson and Makkar2013; Eckard and Clark, Reference Eckard and Clark2018). Thus, our intent is not to cite the vast numbers of individual papers published, but rather, present a critical analysis of the current knowledge gaps and prospects for CH4 mitigation in view of the need for food security. We focus the discussion on knowledge learned, unresolved issues and future challenges for science, governments, farmers and ruminant livestock industries.

Historical perspective

A search of the literature related to rumen methanogenesis published between 1960 and 2018 (Scopus keywords: methane OR methanogenesis AND cow OR cattle OR sheep OR lamb OR rumen) revealed almost 9000 papers (Figure 1). In vitro (e.g. Bauchop, Reference Bauchop1967) and in vivo (e.g. Clapperton, Reference Clapperton1974) research on inhibiting rumen methanogenesis started with the aim of improving energy utilization efficiency of rumen fermentation, with the ultimate goal of improving animal productivity. Some of the studies prior to the year 2000 also established many of the fundamentals of rumen methanogenesis, including rumen microbial ecology, carbohydrate fermentation and associated biochemical pathways, and modifiers of ruminal microbial activity and effects on methanogenesis (Hobson and Stewart, Reference Hobson and Stewart1997). Early animal studies focused on energetics and reported CH4 losses account for 2% to 12% of the gross energy consumed by ruminants (Johnson and Johnson, Reference Johnson and Johnson1995). Many of the factors affecting energy losses as CH4 were revealed including level of intake, carbohydrate type and lipid supplementation. Early animal studies were conducted in respiratory calorimetry chambers (whole animal chambers, head boxes and face masks), with the development of the sulphur hexafluoride tracer gas technique in the early 1990s being a significant innovation providing researchers with a low-cost means of measuring CH4 production of individual animals without the need for restraint or enclosure (Johnson and Johnson, Reference Johnson and Johnson1995). In the early 2000s, the number of CH4-related publications increased rapidly, reflecting significant investment and shift in research focus towards mitigation in view of the increasing awareness of the environmental impact of CH4 from ruminants (Figure 1).

Figure 1 Number of published papers related to enteric methanogenesis (Scopus search keywords: methane OR methanogenesis AND cow OR cattle OR sheep OR lamb OR rumen (total = 5845). A shift in research focus from energy metabolism to environment occurred in the early 2000s, indicating significant recent investment in CH4 mitigation research.

Rumen fermentation and microbiome associated with methanogenesis

Carbohydrates are the main dietary source of energy for ruminants. In the rumen, polysaccharides (mainly cellulose, hemicellulose and starch) are hydrolysed to glucose and other hexoses and pentoses (Figure 2). Monosaccharides are further metabolized to volatile fatty acids (VFAs) and CO2. Metabolic hydrogen ([H]) is released in the metabolism of monosaccharides to VFA, reducing intracellular co-factors, and for fermentation to continue, co-factors must be re-oxidized. This happens to a large extent through hydrogenase activity and formation of dihydrogen (H2, i.e. molecular hydrogen). Ruminal H2 exists in two forms, dissolved H2 (dH2) and gaseous H2 (gH2), with only dH2 being available for microorganisms (Wang et al., Reference Wang, Sun, Janssen, Tang and Tan2014). Dihydrogen does not accumulate in the rumen because it is transferred from the fermentative consortium of bacteria, protozoa and fungi to methanogenic archaea that use it to reduce CO2 and other one-carbon compounds via the hydrogenotrophic pathway to CH4. Most methanogens can also utilize formate generated in acetyl-CoA formation from pyruvate as a [H] donor for ruminal methanogenesis (Schauer and Ferry, Reference Schauer and Ferry1980), with the unused formate being rapidly converted to H2 and CO2. To a much lesser extent, CH4 can also be produced in the rumen through the utilization of methyl groups (methylotrophic pathway) and less commonly from acetate (Huws et al., Reference Huws, Creevey, Oyama, Mizrahi, Denman, Popova, Muñoz-Tamayo, Forano, Waters, Hess, Tapio, Smidt, Krizsan, Yáñez-Ruiz, Belanche, Guan, Gruninger, McAllister, Newbold, Roehe, Dewhurst, Snelling, Watson, Suen, Hart, Kingston-Smith, Scollan, do Prado, Pilau, Mantovani, Attwood, Edwards, McEwan, Morrisson, Mayorga, Elliott and Morgavi2018).

Figure 2 Scheme of the major pathways of rumen fermentation including generation and incorporation of metabolic hydrogen ([H]) and dihydrogen (H2). Estimated Gibbs energy changes are based on Kohn and Boston (Reference Kohn, Boston, McNamara, France and Beever2000) and Ungerfeld and Kohn (Reference Ungerfeld, Kohn, Sejrsen, Hvelpund and Nielsen2006) without considering ATP generation. Generation and incorporation of [H] are estimated based on 1 mol of glucose fermentation according to the following reactions: C6H12O6 (glucose)→2 C3H4O3 (pyruvate)+ 2 [2H]; 2 C3H4O3 + 2 HSCoA (non-esterified coenzyme A) → 2 C2H3OSCoA (acetyl coenzyme A) + 2 CO2 + 4 [2H]; C2H3OSCoA + H2O (water) →→ C2H4O2 (acetate) + HSCoA; 2 C2H3OSCoA + 2 [2H] → C4H8O2 (butyrate) + 2 HSCoA; 2 C3H4O3 + 2 [2H] → 2 C3H6O3 (lactate); 2 C3H6O3 + 2 [2H] → 2 C3H6O2 (propionate) + 2 H2O; 2 C3H4O3 + 2 [2H] + 2 CO2 (carbon dioxide) → 2 C4H6O5 (malate); 2 C4H4O4 (fumarate) + 2 [2H] →→ 2 C3H6O2 + 2 CO2.

Thus, CH4 represents the largest sink of [H] in the rumen. Importantly, while most [H] produced by the fermentative microbiota is transferred to methanogens as dH2 and used in methanogenesis (Janssen, Reference Janssen2010), there are other important pathways of [H] utilization such as propionate production, which can incorporate [H] in reduced co-factors generated in intracellular reactions as well as dH2 produced by other cells (Henderson, Reference Henderson1980; Figure 2). A strong positive relationship between the concentrations of dH2 and propionate indicates that increased ruminal dH2 can facilitate reactions incorporating [H] into propionate production (Wang et al., Reference Wang, Wang, Xie, Janssen, Sun, Beauchemin, Tan and Gao2016).

When methanogenesis is inhibited in vitro, gH2 can accumulate up to 100 times the control treatments with functional methanogenesis (Chalupa et al., Reference Chalupa, Corbett and Brethour1980). In vivo gH2 emissions can increase by 60- (Hristov et al., Reference Hristov, Oh, Giallongo, Frederick, Harper, Weeks, Branco, Moate, Deighton, Williams, Kindermann and Duval2015) or even 600-fold (Vyas et al., Reference Vyas, Alemu, McGinn, Duval, Kindermann and Beauchemin2018) when CH4 production is inhibited. Although the release of gH2 represents an inefficiency of energy utilization, the loss of energy as H2 represents on average only 2.7% of the energy potentially available from the decrease in CH4 production (Ungerfeld, Reference Ungerfeld2018).

Propionate, an alternative [H] sink to CH4 (Janssen, Reference Janssen2010), is the main glucose precursor for ruminants, and therefore desirable to enhance in animals with high demands for glucogenic precursors. Reductive acetogenesis, the formation of acetate from CO2 and H2 (Figure 2), is also a desirable [H] incorporating process, as acetate is an energy source and building block in long chain fatty acid synthesis. However, reductive acetogenesis is thermodynamically outcompeted by methanogenesis in the normal rumen (Ungerfeld and Kohn, Reference Ungerfeld, Kohn, Sejrsen, Hvelpund and Nielsen2006) but would be a beneficial [H] sink to enhance in a methanogenesis-inhibited rumen fermentation (Ungerfeld, Reference Ungerfeld2013). Some inorganic electron acceptors like nitrate and sulphate (Figure 2) can thermodynamically outcompete methanogenesis in the rumen (Ungerfeld and Kohn, Reference Ungerfeld, Kohn, Sejrsen, Hvelpund and Nielsen2006), although the availability of these [H] acceptors is low with most diets unless these electron-accepting compounds are supplemented.

In theory, redirecting [H] away from methanogenesis to fermentation end-products that can be absorbed and utilized by the host animal, as well as to microbial biomass synthesis, helps to not only decrease CH4 emissions but may potentially also benefit productivity of the host animal (see the ‘Methane, animal productivity and incentives to lower emissions’ section). So far, however, this potential has not been consistently realized (Ungerfeld, Reference Ungerfeld2018).

The rumen microbiome associated with methane emissions

There have been tremendous advances made in characterizing archaea responsible for methanogenesis in the rumen, including the variability among animals and how the archaea are affected by diet and mitigation strategies (Henderson et al., Reference Henderson, Cox, Ganesh, Jonker, Young and Janssen2015; Tapio et al., Reference Tapio, Snelling, Strozzi and Wallace2017; Huws et al., Reference Huws, Creevey, Oyama, Mizrahi, Denman, Popova, Muñoz-Tamayo, Forano, Waters, Hess, Tapio, Smidt, Krizsan, Yáñez-Ruiz, Belanche, Guan, Gruninger, McAllister, Newbold, Roehe, Dewhurst, Snelling, Watson, Suen, Hart, Kingston-Smith, Scollan, do Prado, Pilau, Mantovani, Attwood, Edwards, McEwan, Morrisson, Mayorga, Elliott and Morgavi2018; Seshadri et al., Reference Seshadri, Leahy, Attwood, Teh, Lambie, Cookson, Eloe-Fadrosh, Pavlopoulos, Hadjithomas, Varghese, Paez-Espino, Perry, Henderson, Creevey, Terrapon, Lapebie, Drula, Lombard, Rubin, Kyrpides, Henrissat, Woyke, Ivanova and Kelly2018). Henderson et al. (Reference Henderson, Cox, Ganesh, Jonker, Young and Janssen2015) conducted a comprehensive global census of the microbial community composition of rumen and foregut samples (from 379 cattle, 106 sheep, 59 deer, 52 goat and 72 others) from 35 countries. Although the samples were from a wide range of animals, locations, diets and conditions, the dominant archaeal groups were surprisingly similar. Methanobrevibacter gottschalkii and Mbb. ruminantium were found in almost all samples, accounting for, on average, 74% of all archaea. Together with a Methanosphaera sp. and two Methanomassiliicoccaceae-affiliated groups, the five dominant methanogen groups comprised almost 90% of the archaeal communities. About 78% of archaea were hydrogenotrophic, while 22% were methylotrophic using methyl groups from methanol or methylamines, whereas methanogens that used acetate were rare (Seshadri et al., Reference Seshadri, Leahy, Attwood, Teh, Lambie, Cookson, Eloe-Fadrosh, Pavlopoulos, Hadjithomas, Varghese, Paez-Espino, Perry, Henderson, Creevey, Terrapon, Lapebie, Drula, Lombard, Rubin, Kyrpides, Henrissat, Woyke, Ivanova and Kelly2018). It appears that rumen archaea are much less diverse than rumen bacteria, which probably reflects the narrow range of substrates they use. This limited diversity provides an opportunity to develop CH4 mitigation strategies that target these few dominant methanogens. Recent whole genome sequencing of rumen methanogens has provided insight into their metabolic processes (Seshadri et al., Reference Seshadri, Leahy, Attwood, Teh, Lambie, Cookson, Eloe-Fadrosh, Pavlopoulos, Hadjithomas, Varghese, Paez-Espino, Perry, Henderson, Creevey, Terrapon, Lapebie, Drula, Lombard, Rubin, Kyrpides, Henrissat, Woyke, Ivanova and Kelly2018), which could lead to the development of microbiome-based mitigation approaches, such as small molecule inhibitors that target enzymes, vaccines and other approaches that affect the rumen archaea (Leahy et al., Reference Leahy, Kelly, Ronimus, Wedlock, Altermann and Attwood2013).

High-throughput sequencing has been used to study relationships between CH4 production and the microbial community composition quantified in terms of 16S rRNA or 18S rRNA gene abundance, as well as functional gene abundance and expression. The reader is directed to several excellent reviews (e.g. Leahy et al., Reference Leahy, Kelly, Ronimus, Wedlock, Altermann and Attwood2013; Tapio et al., Reference Tapio, Snelling, Strozzi and Wallace2017; Wallace et al., Reference Wallace, Snelling, McCartney, Tapio and Strozzi2017; Huws et al., Reference Huws, Creevey, Oyama, Mizrahi, Denman, Popova, Muñoz-Tamayo, Forano, Waters, Hess, Tapio, Smidt, Krizsan, Yáñez-Ruiz, Belanche, Guan, Gruninger, McAllister, Newbold, Roehe, Dewhurst, Snelling, Watson, Suen, Hart, Kingston-Smith, Scollan, do Prado, Pilau, Mantovani, Attwood, Edwards, McEwan, Morrisson, Mayorga, Elliott and Morgavi2018). Most (Shi et al., Reference Shi, Moon, Leahy, Kang, Froula, Kittelmann, Fan, Deutsch, Gagic, Seedorf, Kelly, Atua, Sang, Soni, Li, Pinares-Patino, McEwan, Janssen, Chen, Visel, Wang, Attwood and Rubin2014; Danielsson et al., Reference Danielsson, Dicksved, Sun, Gonda, Müller, Schnurer and Bertilsson2017), but not all (Wallace et al., Reference Wallace, Rooke, McKain, Duthie, Hyslop, Ross, Waterhouse, Watson and Roehe2015), studies report weak or no relationships between CH4 production of individual animals and total abundance of archaea. Rather, it appears that the composition of the archaeal community and differential gene expression of methanogenesis pathways are more highly associated with CH4 production (Shi et al., Reference Shi, Moon, Leahy, Kang, Froula, Kittelmann, Fan, Deutsch, Gagic, Seedorf, Kelly, Atua, Sang, Soni, Li, Pinares-Patino, McEwan, Janssen, Chen, Visel, Wang, Attwood and Rubin2014; Wallace et al., Reference Wallace, Rooke, McKain, Duthie, Hyslop, Ross, Waterhouse, Watson and Roehe2015; Danielsson et al., Reference Danielsson, Dicksved, Sun, Gonda, Müller, Schnurer and Bertilsson2017). Studies have also shown an association between CH4 production and the abundance of 16S rRNA genes of specific bacterial phyla and genera (Wallace et al., Reference Wallace, Rooke, McKain, Duthie, Hyslop, Ross, Waterhouse, Watson and Roehe2015; Danielsson et al., Reference Danielsson, Dicksved, Sun, Gonda, Müller, Schnurer and Bertilsson2017). As well, a positive association was reported between CH4 production and protozoa (Tapio et al., Reference Tapio, Snelling, Strozzi and Wallace2017), but surprisingly no association was found between archaea and protozoa in the global rumen census (Henderson et al., Reference Henderson, Cox, Ganesh, Jonker, Young and Janssen2015).

A positive association between CH4 production and the abundance of functional genes encoding for methanogenesis enzymes has been reported in some studies (Shabat et al., Reference Shabat, Sasson, Doron-Faigenboim, Durman, Yaacoby, Berg Miller, White, Shterzer and Mizrahi2016). Transcription of the entire methanogenesis pathway was augmented in high-emitting sheep (Shi et al., Reference Shi, Moon, Leahy, Kang, Froula, Kittelmann, Fan, Deutsch, Gagic, Seedorf, Kelly, Atua, Sang, Soni, Li, Pinares-Patino, McEwan, Janssen, Chen, Visel, Wang, Attwood and Rubin2014). It is tempting to speculate that a positive relationship between CH4 production and the abundance of genes encoding for methanogenesis enzymes or their transcripts might indicate that the rate of CH4 formation is kinetically controlled by the activity of one or more methanogenic enzymes. Yet, cause–effect relationships were not demonstrated in the studies discussed, thus the inverse might occur and methanogens may grow and regulate the expression of genes encoding for methanogenesis enzymes depending on other limitations to producing CH4 (Browne and Cadillo-Quiroz, Reference Browne and Cadillo-Quiroz2013). Methanogenesis might be enzyme limited after feeding, when the elevation of dH2 concentration precedes the increase in CH4 and methanogen 16S rRNA gene copies or methanogenesis mRNA transcripts (van Lingen et al., Reference van Lingen, Edwards, Vaidya, van Gastelen, Saccenti, van den Bogert, Bannink, Smidt, Plugge and Dijkstra2017).

Increasing our understanding of the complexity of the rumen microbiome in relation to host and external factors (e.g. diet, mitigation) is key to decreasing CH4 production from ruminants in the future, in addition to maximizing the efficient use of feed resources. Advances in enzyme and gene-based approaches may facilitate the future development of CH4 mitigation compounds that specifically target methanogens and their enzymes (Henderson et al., Reference Henderson, Cook and Ronimus2018), including ongoing efforts to sequence complete genomes of methanogens (e.g. Leahy et al., Reference Leahy, Kelly, Ronimus, Wedlock, Altermann and Attwood2013; Li et al., Reference Li, Leahy, Jeyanathan, Henderson, Cox, Altermann, Kelly, Lambie, Janssen, Rakonjac and Attwood2016). Metagenomic and metatranscriptomic research to reveal the complexities and functionality of the rumen microbiome should continue to be an area of high-priority research to improve the environmental sustainability of ruminant production.

Strategies for mitigating methane emissions

While numerous strategies have been proposed for CH4 mitigation (Hristov et al., Reference Hristov, Oh, Lee, Meinen, Montes, Ott, Firkins, Rotz, Dell, Adesogan, Yang, Tricarico, Kebreab, Waghorn, Dijkstra, Oosting, Gerber, Henderson and Makkar2013; Knapp et al., Reference Knapp, Laur, Vadas, Weiss and Tricarico2014), many are difficult to implement on-farm (e.g. protozoa defaunation), have low mitigation potential (e.g. yeast, bacterial direct-fed microbials, saponin, ionophores) or are at a very early stage of development (e.g. bacteriocins, phages). Accordingly, the following discussion focuses on mitigation strategies with potential for on-farm adoption in the short or medium term (Table 1).

Table 1 Assessment of select strategies for enteric methane mitigation in the short or medium term based on the information provided in the text

Increasing animal productivity

Improved animal performance through superior animal management, health, nutrition and genetics lowers CH4 emission intensity (g CH4/kg product) because fewer animals and consequently less total feed are used to produce a given amount of product (Capper et al., Reference Capper, Cady and Bauman2009). However, absolute emissions (g/animal per day) may increase as animals consume additional feed to meet their energy requirements. There are many industry-wide examples that illustrate how improvements in animal performance over time have decreased CH4 and total GHG emissions intensity (e.g. Capper et al., Reference Capper, Cady and Bauman2009; Legesse et al., Reference Legesse, Beauchemin, Ominski, McGeough, Kroebel, MacDonald, Little and McAllister2016). However, CH4 intensity decreases in a curvilinear manner with increased animal productivity; thus, increasing the productivity of lower-producing animals has a relatively large impact, whereas a further increase in the productivity of high-producing animals has a relatively small impact. A life cycle assessment that accounts for all changes in GHG associated with the changes in practices to enhance animal productivity is necessary before recommending this approach for CH4 mitigation. Ultimately, for reduction in emissions intensity to translate into absolute reductions in emissions, a net decrease in animal numbers will be required.

Animal breeding

Heritabilities of CH4 production on an absolute emission basis (g CH4/day) are moderate and estimated at 0.29 and 0.40 in sheep and cattle, respectively, but much lower at 0.13 and 0.19, respectively, on a yield basis (g CH4/kg dry matter intake (DMI)) (Pickering et al., Reference Pickering, Oddy, Basarab, Cammack, Hayes, Hegarty, Lassen, McEwan, Miller, Pinares-Patiño and de Haas2015). Incorporating CH4 production in a genetic selection programme represents a major challenge because of the difficulty of measuring CH4 in a manner that reflects the long-term CH4 phenotype of the animal (Løvendahl et al., Reference Løvendahl, Difford, Li, Chagunda, Huhtanen, Lidauer, Lassen and Lund2018). Methane production is mainly driven by DMI and fermentability of the feed, so emissions fluctuate over the long term depending upon the status of the animal and the diet, and diurnally depending upon the timing of feeding. Obtaining accurate and low-cost estimates of CH4 production for a large group of animals under commercial conditions is challenging. Some animal breeding programs use a ‘sniffer’ technique to measure breath CH4 concentration at a feeder or during milking. Although this technique has many sources of error (source-sampling distance, air turbulence, cow’s head movement; Wu et al., Reference Wu, Groot Koerkamp and Ogink2018), it has been shown to be correlated (r = 0.75) to flux methods when used by skilled researchers (Difford et al., Reference Difford, Olijhoek, Hellwing, Lund, Bjerring, de Haas, Lassen and Løvendahl2019). Additionally, the development of proxies (see the ‘Biomarkers to estimate methane emissions’ section) that are highly correlated with CH4 production would be beneficial for identifying low-CH4 animals in a genetic selection program (Negussie et al., Reference Negussie, de Haas, Dehareng, Dewhurst, Dijkstra, Gengler, Morgavi, Soyeurt, van Gastelen, Yan and Biscarin2017).

Relationships between CH4 production and economically important traits are largely unknown (Basarab et al., Reference Basarab, Beauchemin, Baron, Ominski, Guan, Miller and Crowley2013), although Breider et al. (Reference Breider, Mall and Garnsworthy2019) recently showed genetic correlations of 0.49 to 0.54 between CH4 production and milk yield indicating that genetically selecting for lower CH4 production may decrease productivity. Thus, it is not clear whether genetic selection for CH4 traits would provide any further advantage over selection for production traits, such as growth and milk production, which lower CH4 emission intensity (Capper et al., Reference Capper, Cady and Bauman2009; Legesse et al., Reference Legesse, Beauchemin, Ominski, McGeough, Kroebel, MacDonald, Little and McAllister2016). Another major limitation is that economic indexes developed for commercial sire selection are based on multiple traits weighted for their economic value. With the low economic value of CH4 mitigation, this trait would have minor weighting in a multi-trait index. Furthermore, it is not clear whether selecting low-emitting animals may result in reduced feed efficiency (Løvendahl et al., Reference Løvendahl, Difford, Li, Chagunda, Huhtanen, Lidauer, Lassen and Lund2018), especially of high-forage diets, given the finding of Pinares-Patiño et al. (Reference Pinares-Patiño, Ebrahimi, McEwan, Dodds, Clark and Luo2011) that low-CH4 sheep have lower feed digestibility than high-CH4 emitting sheep.

Another approach for lowering CH4 emissions through animal genetics is the selection of more efficient animals based on a measure of feed conversion efficiency such as residual feed intake (which compares the actual feed intake of animals to expected intake for maintenance and production; Kenny et al., Reference Kenny, Fitzsimons, Waters and McGee2018). This trait is moderately heritable (0.26 to 0.43) and moderately repeatable across diets (0.33 to 0.67) (Basarab et al., Reference Basarab, Beauchemin, Baron, Ominski, Guan, Miller and Crowley2013), although there is evidence that animal re-ranking may occur with different types of diets (Kenny et al., Reference Kenny, Fitzsimons, Waters and McGee2018). One limitation for research is that the measurement of residual feed intake requires accurate measurement of DMI of individual animals, which is challenging for grazing animals. Incorporating measures of improved feed efficiency into multi-trait selection-based breeding programs has the potential to reduce the amount of feed used for meat and milk production (lower DMI with minimal change in digestibility). Consequently, a decrease in absolute emissions of enteric CH4 can be expected with improved feed efficiency, but this needs confirmation in additional research using a range of diets to ensure no genotype × environment interaction exists.

Nutrition

Dietary manipulation can be a highly effective CH4 mitigation approach, and many thorough reviews are available (Beauchemin et al., Reference Beauchemin, McAllister and McGinn2009; Hristov et al., Reference Hristov, Oh, Lee, Meinen, Montes, Ott, Firkins, Rotz, Dell, Adesogan, Yang, Tricarico, Kebreab, Waghorn, Dijkstra, Oosting, Gerber, Henderson and Makkar2013; Knapp et al., Reference Knapp, Laur, Vadas, Weiss and Tricarico2014). The efficiency of a particular dietary CH4 mitigation strategy depends on its effects on ruminal H2 flow and concentration, the microbial community, fermentation pathways, residence time of feed in the rumen and interactions among these factors.

Lipids

Numerous studies have shown that low levels of lipid supplementation of diets (<4% of dietary DMI) can decrease CH4 production (by up to 20%, although results are variable) while increasing energy density of diets and benefiting animal productivity in some cases. The results from meta-analysis studies indicate a 1% to 5% decrease in CH4 (g/day) per 10 g/kg DM dietary fat (Grainger and Beauchemin, Reference Grainger and Beauchemin2011; Patra, Reference Patra2013) with medium chain (C12:0, C14) and polyunsaturated fatty acids being most potent (Patra, Reference Patra2013). Lipids inhibit methanogenesis by replacing rumen fermentable organic matter in the diet, decreasing the numbers of ruminal methanogens and protozoa, and through biohydrogenation of unsaturated fatty acids (Patra, Reference Patra2013). Biohydrogenation can provide an alternative [H] sink in the rumen to compete with methanogenesis, but this is quantitatively small (1% to 2% of [H] used for this reaction; Nagaraja et al., Reference Nagaraja, Newbold, Van Nevel, Demeyer, Hobson and Steward1997), albeit potentially greater when methanogenesis is inhibited. However, lipid supplementation is often costly and can decrease fibre digestibility and DMI, inhibit rumen fermentation, depress milk fat synthesis and alter the fatty acid composition of products (Grainger and Beauchemin, Reference Grainger and Beauchemin2011; Patra, Reference Patra2013). Although lipid supplementation can be implemented immediately on commercial farms, overall it has low to moderate scope for CH4 mitigation due to cost and potential negative effects on animal production and product quality.

Concentrates

Compared to forage-based diets, concentrate-based diets are associated with lower CH4 yield (g/kg DMI; Johnson and Johnson, Reference Johnson and Johnson1995) because fermentation of starch in concentrate results in more propionate and butyrate than cellulose in forage and thus competes with methanogenesis for [H]. Starch has a faster rate of digestion and fermentation than cellulose, resulting in elevated dH2 (Wang et al., Reference Wang, Sun, Janssen, Tang and Tan2014). Additionally, high-starch intake can decrease ruminal pH, which inhibits the growth of methanogens, but it can also reduce fibre digestibility and increase the risk of acidosis. While increased feeding of starch-based diets may improve animal performance and decrease CH4 yield, its potential as a CH4 mitigation strategy is low as the global capacity to increase concentrate feeding of ruminants is limited. Furthermore, grain-based diets ignore the importance of ruminants in converting fibrous feeds, unsuitable for human consumption, to high-quality protein sources (i.e. milk and meat). Changes in the emissions of GHG resulting from producing additional concentrate and land use change also need to be considered using a life cycle assessment approach.

Forages

Strategies to mitigate CH4 production from ruminants consuming forage diets are needed given that grazing ruminants produce 75% of global ruminant CH4 emissions (Food and Agriculture Organization of the United Nations, 1999). Some of the CH4 emissions from grazing ruminants can be offset by enhancing soil carbon reserves, thereby removing CO2 from the atmosphere (Guyader et al., Reference Guyader, Janzen, Kroebel and Beauchemin2016b). Additionally, well-managed grazing systems can reduce the use of synthetic fertilizer by more effective use of manure and nitrogen-fixing plants, which decreases N2O emissions. Forage-based ruminant systems also provide many other ecological benefits, such as conserving biodiversity, improving soil health, enhancing water quality and providing wildlife habitat (Guyader et al., Reference Guyader, Janzen, Kroebel and Beauchemin2016b). Mitigation of CH4 from forage-based diets can be achieved to some extent by improving forage quality and availability through grazing management, timing of harvest, use of forage species with superior digestibility, use of condensed tannin-containing plants (see the ‘Phytocompounds’ section) and storage of forages to conserve digestible nutrient content. However, differences in forage quality may not always alter absolute CH4 emissions (g/day) (Beauchemin et al., Reference Beauchemin, McAllister and McGinn2009). On the one hand, high-quality forage has a greater ratio of non-fibre carbohydrates to NDF and less lignified NDF, which promotes organic matter degradation in the rumen. Therefore, more [H] is available for methanogenesis and absolute CH4 production is increased due to greater DM ingested and digested in the rumen. On the other hand, high-quality forage promotes greater DMI in animals, which is associated with greater rate of passage from the rumen, and decreased CH4 per gram of DMI. Also, animals fed high-quality forages are more productive and thus have lower CH4 emission intensity. As a result, the net effects of forage quality on daily CH4 emissions can be variable, but improved forage quality typically lowers emissions intensity as a result of enhanced animal productivity.

Rumen fermentation and microbiome manipulation

Vaccines

Vaccination against rumen methanogens has been promoted as a means of decreasing CH4 emissions and would be particularly useful for pasture-based systems for which many other mitigation approaches cannot be easily implemented. The concept is based on the vaccine inducing the animal’s immune system to produce antibodies in saliva, which upon entry into the rumen would suppress the growth of methanogens (Subharat et al., Reference Subharat, Shu, Zheng, Buddle, Kanek, Hook, Janssen and Wedlock2016). Current vaccine development by AgResearch (Hamilton, New Zealand) targets cell surface proteins that are conserved among rumen methanogens (https://www.nzagrc.org.nz/vaccine.html). So far, research has demonstrated production of antibodies in vivo in response to a vaccine (Wedlock et al., Reference Wedlock, Pedersen, Denis, Dey, Janssen and Buddle2010; Zhang et al., Reference Zhang, Huang, Xue, Peng, Wang, Yan and Wang2015); however, changes in rumen methanogen population or CH4 emissions have been nominal (Eckard and Clark, Reference Eckard and Clark2018). Although a challenging undertaking, a vaccine, if successful, could make substantial contribution to CH4 mitigation, although effects on animal health and productivity will need to be established.

Early life programming

Recent studies have focused on decreasing CH4 formation through programming the rumen microbial community early in the animal’s life, as reviewed by Yáñez-Ruiz et al. (Reference Yáñez-Ruiz, Abecia and Newbold2015). The central idea is that the developing microbial community of the newborn ruminant is more malleable so that its manipulation is more likely to have long-lasting effects compared to the established microbiome of the adult animal. There are reports of colonization of the rumen by methanogens as early as birth (Guzman et al., Reference Guzman, Bereza-Malcolm, De Groef and Franks2015). Research with gnotobiotic animals also provides important insights about the potential of rumen manipulation in early life and the potential alternative [H] sinks to CH4 that could be enhanced in the developing rumen.

Abecia et al. (Reference Abecia, Martín-García, Martínez, Newbold and Yañez-Ruiz2013) observed that treating both does and their kids with the methanogenesis inhibitor bromochloromethane (BCM) resulted in less CH4 emissions and greater rumen propionate concentration in kids when measured 3 months after BCM treatment of does and kids had ceased. The archaeal community composition also differed between treatments, but only if the mothers had also been treated with BCM, indicating that treating the mothers may be an additional means of influencing the early development of the rumen microbial community (Abecia et al., Reference Abecia, Martinez-Fernandez, Waddams, Martin-Garcia, Pinloche, Creevey, Denman, Newbold and Yanez-Ruiz2018). Other studies showed no long-lasting effects on CH4 production when anti-methanogenic (garlic essential oil and linseed oil) treatments were given to neonatal lambs (Saro et al., Reference Saro, Hohenester, Bernard, Lagree, Martin, Doreau, Boudra, Popova and Morgavi2018). It remains to be determined how the persistence of early life methanogenesis intervention is affected by the treatment applied, the animal and the diet, among other variables. Although some early life studies have reported decreased methanogenesis in the short-term post-treatment, it will be necessary to assess whether mitigation is maintained throughout adulthood, the mechanisms involved and implications for animal health and performance. As the research is at an early stage, the feasibility of implementation on commercial farms where animals are in constant contact with each other is unknown.

Chemical inhibitors

The search for compounds that decrease CH4 production when fed to ruminants is an important area of research, although challenging. In addition to CH4 abatement, research in this area may theoretically lead to improved production efficiency through redirection of [H] from CH4 towards compounds such as propionate or acetate formed through reductive acetogenesis that can be used by the animal (Janssen, Reference Janssen2010; Ungerfeld, Reference Ungerfeld2013). The most common approach has been to use compounds that directly inhibit methanogenesis. Such compounds need to persistently lower emissions without toxic effects for animals, humans and the environment, and in order to be adopted by producers, they may need to be low cost and increase productivity and profitability. Furthermore, such compounds need to undergo thorough and costly regulatory processes before being commercially available. While the enormous cost and complexity of developing new compounds that are not already deemed safe for feeding to animals is daunting, this area of research should be a high priority.

Use of chemically synthesized inhibitors is one of the most promising strategies to decrease CH4 emissions from ruminants (Liu et al., Reference Veneman, Saetnan, Clare and Newbold2011; Veneman et al., Reference Veneman, Saetnan, Clare and Newbold2016; Henderson et al., Reference Henderson, Cook and Ronimus2018). Most inhibitors evaluated can be classified as analogues of CH4 or analogues of methyl-coenzyme M, a co-factor involved in methyl transfer during methanogenesis. Some inhibitors that have been evaluated in vivo are trichloroacetamide, hemiacetal of chloral and starch, BCM, chloral hydrate, 9, 10-anthraquinone, nitroethane, 3-nitrooxypropanol (3-NOP) and chloroform (Ungerfeld, Reference Ungerfeld2018). Some inhibitors are toxic, cause undesirable side effects or decrease methanogenesis only transiently, yet their study has generated useful proof of concept knowledge about the consequences of inhibiting rumen methanogenesis.

3-Nitrooxypropanol is a promising experimental CH4 inhibitor currently under evaluation in large-scale dairy and beef cattle studies to support licencing by government authorities. Consistent CH4 yield decreases of 20% to 40% have been reported depending upon animal, diet composition, dose and method of supplementing 3-NOP (Hristov et al., Reference Hristov, Oh, Giallongo, Frederick, Harper, Weeks, Branco, Moate, Deighton, Williams, Kindermann and Duval2015; Dijkstra et al., Reference Dijkstra, Bannink, France, Kebreab and van Gastelen2018; Vyas et al., Reference Vyas, Alemu, McGinn, Duval, Kindermann and Beauchemin2018). No negative effects on diet digestibility (Romero-Perez et al., Reference Romero-Perez, Okine, McGinn, Guan, Oba, Duval and Beauchemin2014) and sustained decrease of CH4 production over several months have been reported for lactating dairy cows (25% to 32%, 12-week study; Hristov et al., Reference Hristov, Oh, Giallongo, Frederick, Harper, Weeks, Branco, Moate, Deighton, Williams, Kindermann and Duval2015) and growing beef cattle (high-forage diet for 105 days, 37% decrease; high-grain diet for 105 days, 42% decrease; Vyas et al., Reference Vyas, Alemu, McGinn, Duval, Kindermann and Beauchemin2018). However, a study by McGinn et al. (Reference McGinn, Flesch, Beauchemin and Shreck2019) suggests that there may be an adaptation to inhibitors over time, which is an area of research that needs to be pursued.

3-Nitrooxypropanol is a small molecule with a molecular shape similar to that of methyl-coenzyme M (Duin et al., Reference Duin, Wagner, Shima, Prakash, Cronin, Yáñez-Ruiz, Duval, Rümbeli, Stemmler, Thauer and Kindermann2016). The methylated forms of coenzymes M and B are utilized as substrates by the nickel enzyme methyl-coenzyme M reductase in the last step of methanogenesis. 3-Nitrooxypropanol preferably binds into the active site of the reductase and then inactivates the reductase by oxidation of its active site Ni(I) (i.e. the nickel containing co-factor F430 of the reductase has to be in Ni(I) state for it to be active; Duin et al., Reference Duin, Wagner, Shima, Prakash, Cronin, Yáñez-Ruiz, Duval, Rümbeli, Stemmler, Thauer and Kindermann2016). The effective dose of 3-NOP is relatively low (1–2 g/day), has high specificity towards methanogens, is degraded in the rumen to very low concentrations of nitrate, nitrite and 1,3-propanediol, residues in milk and meat are minute or non-existent and the safety risks of 3-NOP are reportedly low (Thiel et al., Reference Thiel, Rümbeli, Mair, Yeman and Beilstein2019a and Reference Thiel, Schoenmakers, Verbaan, Chenal, Etheve and Beilstein2019b), although it waits to be seen whether the compound is approved by the regulatory authorities. Thus, 3-NOP has tremendous potential for CH4 mitigation if commercially available, but product cost and consumer acceptance will factor into the acceptance of such a compound.

Algae

Algae can be classified by size (micro or macro) with macroalgae (seaweed) further classified based on pigmentation (green, red or brown) and habitat (freshwater, marine). Some types of algae concentrate phlorotannin and bromoforms, halogenated compounds that inhibit cobamide-dependent coenzyme M during methanogenesis. Machado et al. (Reference Machado, Magnusson, Paul, de Nys and Tomkins2014) screened 20 species of tropical marine macroalgae in vitro and concluded that Dictyota (brown) and Asparagopsis (red) had the most potential for CH4 production decrease. Kinley et al. (Reference Kinley, de Nys, Vucko, Machado and Tomkins2016) further showed in vitro that Asparagopsis taxiformis supplemented at 20 g/kg of forage almost eliminated CH4 production without negative effects on forage digestibility. Recently, Li et al. (Reference Li, Norman, Kinley, Laurence, Wilmot, Bender, de Nys and Tomkins2018) reported that feeding diets supplemented with up to 3% A. taxiformis to sheep decreased CH4 production in a dose-dependent manner over a 72-day period, with 80% mitigation at the greatest dose and no changes in body mass gain. For algae to be adopted by farmers, a decrease in methanogenesis without negative side effects would have to be persistent. The safety of feeding bromoform-containing macroalgae to livestock will also need to be investigated, as bromoform can be toxic to the environment (i.e. ozone depletion) and can impair human health. Furthermore, a life cycle assessment will need to examine the CO2 emissions from producing, harvesting, drying and transporting algae, which may offset potential decreases in CH4 emissions from ruminants.

Alternative [H] sinks

Nitrate is a competitive [H] acceptor in the rumen that uses [H] at the expense of methanogenesis during its reduction to nitrite and subsequently ammonia. Additionally, nitrate can exert direct toxic effects on methanogens through its reduction intermediate nitrite (Lee and Beauchemin, Reference Lee and Beauchemin2014). Stoichiometrically, reduction of 1 mol (62 g) of nitrate to ammonia in the rumen should lower CH4 production by 1 mol (16 g). However, in feeding studies this potential is never reached because both nitrate and nitrite can be absorbed from or passed out of the rumen, increasing the risk of toxicity, and nitrite may be undesirably metabolized to other end-products such as N2O, another potent GHG. A number of feeding studies have examined the short- and long-term effects of nitrate supplementation of diets (mainly as calcium nitrate). In studies lasting several months, dietary inclusion of nitrate (about 20 g/kg DM) persistently lowered CH4 by up to 12% in beef cattle (Lee et al., Reference Lee, Araujo, Koenig and Beauchemin2017) and 16% in dairy cows (van Zijderveld et al., Reference van Zijderveld, Gerrits, Dijkstra, Newbold, Hulshof and Perdok2011). Nitrate is a source of non-protein N and can help supply the N requirements of the rumen microorganisms, which can be beneficial for low-protein diets, but the addition of nitrate to a diet already sufficient in N would result in increased N voided to the environment. Feeding nitrate to animals slightly increases nitrate residues in tissues (Doreau et al., Reference Doreau, Arbre, Popova, Rochette and Martin2018) and milk (Guyader et al., Reference Guyader, Doreau, Morgavi, Gérard, Loncke and Martin2016a), but the levels are very low and not considered harmful to humans. However, increased nitrate concentrations in the rumen cause nitrate and methemoglobin levels to increase potentially causing nitrate poisoning of animals. Although risk of poisoning can be reduced by gradual adaptation of animals (Lee and Beauchemin, Reference Lee and Beauchemin2014), nitrate supplements are not approved for livestock in many countries (USA, Canada). Overall, the cost of calcium nitrate relative to urea (more than double) and the potential safety risks to animals fed nitrate are major impediments to using nitrate for CH4 mitigation.

Phytocompounds

Secondary plant compounds such as essential oils, tannins, saponins, flavonoids and organosulphur compounds have been investigated for their potential anti-methanogenic properties. One of the most comprehensive studies of this kind is the EU project ‘Rumen-up’ that evaluated 500 plants and plant extracts for their effects on in vitro fermentation and identified at least 25 as having potential value as feed additives (https://www.abdn.ac.uk). Numerous essential oils (e.g. derived from garlic, thyme, eucalyptus, oregano, cinnamon and rhubarb) have been shown to decrease CH4 production in vitro, but very few compounds have been shown to have long-term anti-methanogenic effects in vivo (Cobellis et al., Reference Cobellis, Trabalza-Marinucci and Yu2016). Garlic oil, which contains the organosulphur compounds alliin, diallylsulphides and allicin, appears to be one of the most effective phytocompounds for CH4 decrease in vitro; thus, this effect needs to be evaluated in future animal studies.

Condensed and hydrolysable tannins also offer promise for CH4 mitigation. Tannins are polyphenolic compounds found in various plants with complex and diverse chemical structure that have an affinity to bind to proteins and other compounds. The CH4 response to feeding tannins is highly variable depending upon the source, type and molecular weight of the tannins, and the methanogenic community present in the animal. A meta-analysis of 30 in vitro and in vivo experiments showed that increasing levels of tannins decreased CH4 production expressed relative to digestible organic matter (Jayanegara et al., Reference Jayanegara, Leiber and Kreuzer2012). Furthermore, the in vitro batch culture studies appeared to predict the in vivo responses reasonably well up to a level of 100 g tannins/kg DM. Meta-analysis of the in vivo studies indicated a decrease of 0.109 L CH4/kg DMI per g tannin/kg DMI (r 2 = 0.47). However, a major limitation with tannins is that at low concentrations (<20 g/kg DMI), typical of many forages and feed supplements, CH4 responses are highly variable. Furthermore, part of the CH4 decrease due to tannins can be caused by a concomitant decline in DMI and nutrient digestibility. Nevertheless, the use of tannins as a potential CH4 mitigation strategy warrants further investigation to identify the types and doses of tannins that reduce CH4 without adverse effects on animal performance. Use of tannin-containing forages is particularly relevant for grazing ruminants as many forage legumes contain tannins, condensed tannins have been shown to aid in the control of gastrointestinal parasites (Min and Hart, Reference Min and Hart2003), and tannins can improve N utilization (Jayanegara et al., Reference Jayanegara, Leiber and Kreuzer2012).

Reducing net emissions v. emissions intensity

In discussing CH4 mitigation, it is important to consider the implications of the different metrics used (Eckard and Clark, Reference Eckard and Clark2018). Agricultural supply chain markets increasingly require certification of the carbon footprint of products, an emission intensity metric based on GHG emissions per unit of product produced. However, under the UN Framework Convention on Climate Change (UNFCCC, 2015), signatories have made commitments towards absolute reductions in their national GHG emissions. Fifty-four countries specifically mention a goal of decreasing livestock emissions (Richards et al., Reference Richards, Bruun, Campbell, Gregersen, Huyer, Kuntze, Madsen, Oldvig and Vasileiou2015). A net reduction in GHG emissions will require net reductions in CH4 emissions, yet cost-effective options for decreasing livestock CH4 are limited at present.

A focus on emissions intensity still allows the livestock industries to grow with increasing efficiency of production, while decreasing CH4 emissions relative to a ‘business as usual’ scenario. However, if the rate of growth of meat and milk production as a result of increasing demand for animal products is greater than the decrease in CH4 emissions intensity, absolute CH4 emissions from the livestock sector will continue to increase in the future. Thus, an approach targeting increases in animal productivity and decreases in absolute CH4 emissions of individual animals, possibly combined with a decrease in consumption of livestock products, is needed (Garnett, Reference Garnett2009). Providing livestock producers with cost-effective options for decreasing CH4 emissions is therefore imperative to lower carbon footprint of livestock products while also meeting international targets for net reductions in livestock emissions. There are few examples where both emissions intensity and net decreases in CH4 emissions can be achieved, and this is an area requiring further research.

For increased milk and meat production to fill the increasing demands for food from animal origin to occur, along with a decrease of absolute CH4 emissions from the livestock industry, the decrease in GHG emissions intensity (i.e. including N2O and CO2 emissions) of the livestock industry would have to be proportionally greater than the increase in production. We can envision three possible, non-excluding avenues to achieve substantial decreases in absolute CH4 production. A first possibility is to increase individual animal productivity and efficiency, thus requiring fewer animals and thus generating less total CH4, for the same total production from the industry (Capper et al., Reference Capper, Cady and Bauman2009; Legesse et al., Reference Legesse, Beauchemin, Ominski, McGeough, Kroebel, MacDonald, Little and McAllister2016). Decreasing CH4 intensity through improvements in animal productivity involves intensification and consequences on the emissions of GHG other than CH4 would also need to be considered. While this option is attractive in that it allows the industry to continue growing, net GHG emissions will continue to increase if not accompanied by measures to curb the growth of the industry (e.g. reduced consumption of animal products) or decrease GHG emissions per animal. Furthermore, intensification can lead to greater vulnerability under a changing climate (Henry et al., Reference Henry, Eckard and Beauchemin2018). Thus, improving individual animal productivity as a GHG mitigation approach will likely be insufficient if not accompanied by measures to decrease CH4 emissions per animal. A second possibility is to explore the combination of various anti-methanogenic strategies (Table 1) that when applied together have substantial additive effects (e.g. linseed oil + nitrate; Guyader et al., Reference Guyader, Eugène, Meunier, Doreau, Morgavi, Silberberg, Rochette, Gerard, Loncke and Martin2015). A third possibility is the development and use of specific chemical inhibitors of methanogenesis, such as 3-NOP. However, regulatory approval and consumer acceptance will be required, and improvements in animal performance or government incentives may be necessary to offset the added cost to producers. It is not clear whether greater decrease of CH4 production may be achieved by combining inhibitors with other anti-methanogenic strategies, an area that needs further examination.

Unresolved issues and future direction

Mitigating emissions from extensive ruminant systems

A major constraint for decreasing global enteric CH4 emissions from ruminants is the difficulty of applying mitigation strategies to grazing ruminants. It is estimated that about 60% of global agricultural land is grazed, supporting 360 million cattle and more than 600 million sheep and goats (FAO, 1999). Low-CH4 diet formulations and feed additives are limited to animals fed total or partial mixed rations and very few mitigation approaches are available for pasture-based systems. Hence, most mitigation strategies for pastured ruminants focus on reducing emission intensity through animal breeding, supplementation to improve animal performance, grazing management and forage species selection (i.e. legumes, tannin-containing forages). There is an urgent need to develop additional mitigation strategies for grazing ruminants. Inhibitors (e.g. 3-NOP) offer great potential for CH4 reduction but the challenge is administering these compounds to grazing ruminants. It may be possible to develop a slow release formulation or delivery mechanism such as a pasture mineral block, liquid feed or water containing dissolved inhibitors or other mitigation agent to provide the required daily dose. The potential of self-regulated intake of such compounds needs further investigation, with attention to possible effects on animal health and residues in meat and milk.

Methane, animal productivity and incentives to lower emissions

Some CH4 mitigation approaches increase the cost of feeding, thus a production benefit from decreasing methanogenesis may be needed to encourage widespread adoption by farmers. Theoretically, inhibiting CH4 production increases the efficiency of conversion of digestible energy to metabolizable energy (ME) by decreasing energy losses in gases (Johnson and Johnson, Reference Johnson and Johnson1995). In diets with 70% energy digestibility, energy losses as CH4 range between 3% and 17% of digestible energy consumed. Thus, a moderate decrease in CH4 production (e.g. 25%) may only increase ME by 0.75% to 4.25%, and given the efficiency of conversion of ME to net energy for production (i.e. <65%), it might be difficult to quantify a change in productivity. More severe inhibition of CH4 production (e.g. >50%), without a decrease in DMI or digestibility, may be necessary to cause noticeable increases in animal productivity. Furthermore, the increase in ME resulting from a decrease in CH4 might be smaller than estimated because unusable [H] sinks can accumulate in the methanogenesis-inhibited rumen (e.g. formate; Ungerfeld, Reference Ungerfeld2015). Also, the additional ME may not contribute to greater animal productivity if increased flow of absorbed VFA does not match the animal’s requirements or there are limitations in the supply of other nutrients. Thus, the decrease in CH4 production may have to be substantial to obtain noticeable gains in production.

A second equally important consideration is how much CH4 production can be effectively decreased in a production setting. A meta-analysis on the use of chemical inhibitors of methanogenesis reported average maximal decreases in CH4in vivo for individual experiments of 28% and 48% for milk and growth studies, respectively (Ungerfeld, Reference Ungerfeld2018). The question of why methanogenesis inhibition by chemical compounds has been incomplete and variable is an important one. Compounds like CH4 halogenated analogues, BES and 3-NOP universally target methanogens by inhibiting the last step of methanogenesis (Duin et al., Reference Duin, Wagner, Shima, Prakash, Cronin, Yáñez-Ruiz, Duval, Rümbeli, Stemmler, Thauer and Kindermann2016). It is possible that some rumen methanogens less affected by chemical inhibitors occupy niches left by the most inhibited methanogens, resulting in incomplete inhibition. Metabolism of such compounds also occurs (Duin et al., Reference Duin, Wagner, Shima, Prakash, Cronin, Yáñez-Ruiz, Duval, Rümbeli, Stemmler, Thauer and Kindermann2016) and may partly explain incomplete inhibition. Areas of interest for future research are the differences in the archaeal community and gene expression of methanogenesis pathways induced by anti-methanogenic compounds, the metabolism of these compounds in the rumen and long-term effects of combinations and rotations of chemical inhibitors and other additives and dietary ingredients.

It is often said that decreasing CH4 production is a win–win situation for the environment and livestock producers. However, increased animal performance due to CH4 decrease is still highly speculative, as few studies have been conducted where a substantial decrease in CH4 production was achieved over a long enough period to monitor effects on animal production (Ungerfeld, Reference Ungerfeld2018). In the dairy study by Hristov et al. (Reference Hristov, Oh, Giallongo, Frederick, Harper, Weeks, Branco, Moate, Deighton, Williams, Kindermann and Duval2015) where 32% reduction in CH4 was achieved by supplementing diets with 3-NOP, no improvement in milk production occurred although BW gain tended to increase possibly indicating enhanced body reserves. In the beef study by Vyas et al. (Reference Vyas, Alemu, McGinn, Duval, Kindermann and Beauchemin2018) where approximately 40% decrease in CH4 was achieved using 3-NOP, a 3% to 5% improvement in gain : feed was reported. While there can be potentially promising improvements in animal performance coupled with decreases in CH4 production, further long-term studies are needed.

Biomarkers to estimate methane emissions

While significant progress has been made in methods to measure CH4 production (Hammond et al., Reference Hammond, Crompton, Bannik, Dijkstra, Yánez-Ruiz, O’Kiely, Kebreab, Eugène, Yu, Shingfield, Schwarm, Hristov and Reynolds2016), these techniques are expensive and technically challenging, and thus limited to research. The development of accurate, inexpensive and easy to use proxies for CH4 production of individual animals may enable implementation of low-CH4 management and breeding systems on farms. As reviewed by Negussie et al. (Reference Negussie, de Haas, Dehareng, Dewhurst, Dijkstra, Gengler, Morgavi, Soyeurt, van Gastelen, Yan and Biscarin2017), a range of proxies have been explored including feed intake and behaviour, rumen fermentation metabolites, rumen microbiome, milk composition, membrane lipids (archaeol) of methanogens in faeces and lasers/sniffers that measure CH4 concentration. For dairy cows, use of milk mid-IR spectroscopy to detect fatty acid composition and predict CH4 emissions is based on the principle that the precursors for CH4 and de novo synthesis of milk fatty acids both arise in the rumen. Mid-IR spectroscopy analysis of milk fatty acids has good potential to predict CH4 production of individual cows on commercial dairy farms (van Gastelen and Dijkstra, Reference van Gastelen and Dijkstra2016; Vanlierde et al., Reference Vanlierde, Soyeurt, Gengler, Colinet, Froidmont, Kreuzer, Grandl, Bell, Lund, Olijhoek, Eugène, Martin, Kuhla and Dehareng2018), especially when combined with additional information such as feed intake, nutrient composition of the feed, parity and lactation stage. This approach could allow CH4 production to be incorporated in dairy cow breeding programs. Auffret et al. (Reference Auffret, Stewart, Dewhurst, Duthie, Rooke, Wallace, Freeman, Snelling, Watson and Roehe2018) investigated the microbial communities and genetic markers associated with high/low CH4 emitting cattle varying in breed and diet. They found the methanotrophic Methylomonas genus to be negatively correlated with CH4 production. However, rumen microbiome profiling appears to be a poor to moderately accurate predictor of CH4, and it is also costly and difficult for routine on-farm implementation. Nevertheless, the development of biomarkers for CH4 production is at a relatively early stage and should be a priority area for future research.

Conclusions

A tremendous amount of research has been published in the past 50 years that has improved the understanding of the complex processes of rumen fermentation and methanogenesis in ruminants, and the means by which enteric CH4 production can be mitigated. While significant scientific advances have been made, arguably few cost-effective mitigation strategies are currently available to producers. Individually, most mitigation strategies are likely to have low to moderate (<20%) impact on decreasing CH4 emissions, with the exception of chemical inhibitors, where long-term reductions of 20% to 40% may be feasible in commercial feeding operations. Thus, combining strategies may be necessary to achieve the substantial decreases in CH4 production needed by the ruminant livestock industries and should receive research priority in the near future. Furthermore, there is a paucity of information on the mechanisms and effects of these mitigation strategies on animal performance, animal health and whether they will be accepted by consumers. Continued investment in research is critical because breakthrough technologies based on an understanding of rumen fermentation, microbiome and host animal are needed to achieve the decrease in CH4 required. While substantial decreases in emission intensity (g CH4/animal product) have been attained over the past decades due to production efficiency gains, increasing demand for animal protein, coupled with demands for lower emissions food, will require decreases in both emission intensity and absolute emissions (g CH4/animal per day). Studies are needed to develop strategies to achieve both CH4 mitigation and improvements in animal performance to benefit society and livestock producers. A major constraint for decreasing global enteric CH4 emissions is the difficulty of applying mitigation strategies to grazing ruminants, a challenge that needs further investigation.

Acknowledgements

The authors thank the organising committee of the International Symposium on Ruminant Physiology (ISRP) for their invitation and encouragement to prepare this review. We thank the anonymous reviewers whose critiques and comments greatly improved the manuscript. Dr Min Wang thanks National Natural Science Foundation of China (Grant No. 31561143009), and Dr Emilio Ungerfeld thanks Comisión Nacional de Investigación Científica y Tecnológica, Santiago, Chile, for financial support (project Fondecyt 1160764).

K. A. Beauchemin 0000-0002-5070-4554

Declaration of interest

These authors are unaware of any potential conflict of interest.

Ethics statement

Conducting this review involved no animal handling or procedures.

Software and data repository resources

No data were deposited in an official repository.

References

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Figure 0

Figure 1 Number of published papers related to enteric methanogenesis (Scopus search keywords: methane OR methanogenesis AND cow OR cattle OR sheep OR lamb OR rumen (total = 5845). A shift in research focus from energy metabolism to environment occurred in the early 2000s, indicating significant recent investment in CH4 mitigation research.

Figure 1

Figure 2 Scheme of the major pathways of rumen fermentation including generation and incorporation of metabolic hydrogen ([H]) and dihydrogen (H2). Estimated Gibbs energy changes are based on Kohn and Boston (2000) and Ungerfeld and Kohn (2006) without considering ATP generation. Generation and incorporation of [H] are estimated based on 1 mol of glucose fermentation according to the following reactions: C6H12O6 (glucose)→2 C3H4O3 (pyruvate)+ 2 [2H]; 2 C3H4O3 + 2 HSCoA (non-esterified coenzyme A) → 2 C2H3OSCoA (acetyl coenzyme A) + 2 CO2 + 4 [2H]; C2H3OSCoA + H2O (water) →→ C2H4O2 (acetate) + HSCoA; 2 C2H3OSCoA + 2 [2H] → C4H8O2 (butyrate) + 2 HSCoA; 2 C3H4O3 + 2 [2H] → 2 C3H6O3 (lactate); 2 C3H6O3 + 2 [2H] → 2 C3H6O2 (propionate) + 2 H2O; 2 C3H4O3 + 2 [2H] + 2 CO2 (carbon dioxide) → 2 C4H6O5 (malate); 2 C4H4O4 (fumarate) + 2 [2H] →→ 2 C3H6O2 + 2 CO2.

Figure 2

Table 1 Assessment of select strategies for enteric methane mitigation in the short or medium term based on the information provided in the text