Creating a low enteric methane emission ruminant: what is the evidence of success to the present and prospects for developing economies?
J. P. GoopyMazingira Centre, ILRI, Kenya, PO Box 30709, Nairobi 00100, Kenya; and Department Agriculture and Food, The University of Melbourne, Parkville, Melbourne, Vic. 3052, Australia. Email: j.goopy@cgiar.org
Animal Production Science 59(10) 1769-1776 https://doi.org/10.1071/AN18457
Submitted: 2 August 2018 Accepted: 20 July 2019 Published: 30 August 2019
Journal Compilation © CSIRO 2019 Open Access CC BY-NC-ND
Abstract
Enteric methane emissions from livestock constitute a greater part of anthropogenic greenhouse gases (GHGs) in Africa, than in more industrialised economies, providing a strong incentive for the development of low methane phenotype ruminants. Although dietary and husbandry options already exist for lowering methane production, means of changing ‘methane status’ of animals enduringly has a strong appeal. This paper is a critical review the empirical success to date of attempts to alter this status. Introduction of reductive acetogens, defaunation, anti-methanogen vaccines, early life programming and genetic selection at both the rumen and animal level are considered in turn. It is concluded that to date, there is little in vivo evidence to support the practical success of any of these strategies, save selective breeding, and this at a high cost with unknown efficacy. Finally, it is suggested that for developing economies management and nutritional strategies to reduce emissions will have the greatest and most immediate impact, at the lowest cost.
Additional keywords: anti-methanogen, defaunation, early life programming, reductive acetogenesis, rumen biome.
Introduction
Enteric methane emissions from ruminants are of wide concern to government, to environmentalists, aid organisations, and arguably to the wider or general community, because of the interrelationships between food production, human health and enteric methane’s adverse effect on climate. It has been argued that it would be best if domestic ruminants were eliminated as a human food source (Sabaté and Soret 2014); however, others suggest that such an action would not be an efficient use of available resources and question if the future human population could meet its food needs if such a course were adopted (Rojas-Downing et al. 2017). This is crucially so in sub-Saharan Africa where the consumption of animal-based proteins is low, but essential to the basic nutritional requirements of some of the world’s most economically vulnerable people. Unfortunately, large livestock numbers with low productivity and relatively low levels of industrial development mean that the ruminant contribution to anthropometric greenhouse gas (GHG) emissions on the African continent is the largest component of national GHG inventories in many countries. This provides a compelling case for developing and implementing practical and effective strategies to reduce GHG emissions in African livestock.
Enteric emissions can be reduced or mitigated in several ways. Several dietary manipulations such as the use of lipids (Machmüller et al. 2000) or chemical feed additives (e.g. bromochloromethane; (Denman et al. 2007), have been demonstrated to reduce enteric methane production in ruminants. Improving animal productivity and thereby decreasing emissions per unit of animal product produced is well recognised as an effective way to reduce the carbon footprint of livestock. Dietary and management strategies to ameliorate the impact of ruminants on GHG levels have been the subject of considerable scientific enquiry and has been well summarised in several authoritative reviews (Beauchemin et al. 2008; Hegarty et al. 2010).
Regardless of known and effective strategies for reducing enteric emissions, the impetus to create, or develop ruminants that emit lower levels of methane permanently or semi-permanently, without the need for ongoing (human) intervention is strong. Theoretically, as many have claimed (Iqbal et al. 2008; Mitsumori and Sun 2008; Kumar et al. 2014) this should be achievable, and realising this goal would be a game-changer, particularly in developing economies where ruminant livestock production systems are a significant contributor to emissions The process of enteric methane production is a complex one, involving multiple microbial consortia and their interactions with the host itself (Leng 2018). Thus, there are several potential modalities for interfering or modulating the process of methanogenesis at either at the level of the rumen biome or the mammalian host level. Permanently altering the rumen environment by introducing organisms that compete with or are inimical to rumen Archea, inducing a host immune response to methanogens or genetic selection of a low-methane phenotype animal are all paths by which, at least in theory, enteric methane production may be permanently reduced. However, results in vivo frequently fail to match those predicted by modelling, molecular or in vitro studies. This review specifically examines the animal experimental evidence to date for producing the ‘low methane’ ruminant, whether by manipulating the rumen population or the host, or both.
Changing the animal: altering the rumen microbiome
The rumen is an ecologically complex environment, but there are documented instances of the successful transfer of novel organisms to improve rumen function (Jones and Megarrity 1986). This section examines the evidence of reducing methane production using modalities that attempt to enduringly alter the rumen environment.
Reductive acetogens
The process of reductive acetogenesis (RA) takes the same reactants used in methanogenesis (CO2 + H2) and transforms them into acetate via an alternate biochemical process. This is a process commonly found in anoxic natural systems such as lake sediments, but generally accounts for less than 5% of hydrogen utilisation in these systems (Lovley and Klug 1983) perhaps due to the hydrogen concentration threshold for uptake by methanogens being 10−1 to 10−2 of that for acetogens (Cord-Ruwisch et al. 1988).
Notwithstanding this, establishing the process of reductive acetogenesis in ruminants has become something of a ‘holy grail’ of enteric methane reduction. If acetogenic bacteria could be established and compete effectively in the rumen, this colonisation would have the dual benefit of reducing (possibly eliminating) the animals’ requirement for methanogenesis to dispose of excess hydrogen, while simultaneously providing additional energy substrate for the host animal (resulting in more complete usage of feed). The potential for RA to reduce methane emissions in ruminants was reviewed by Joblin (1999) who concluded that ‘it is too early to discard the possibility for reductive acetogens competing with or acting in concert with methanogens’. However, evidence to suggest that acetogenic bacteria will grow in the conditions prevalent in the rumen, using the process of RA, is sparse. RA, along with methanogenesis, is a critical metabolic process in termites, where acetogens apparently co-exist with methanogens (Breznak and Kane 1990). Schmitt-Wagner and Brune (1999) found that both groups are present in termites because they are highly localised, with acetogens existing where there is the highest partial pressure of hydrogen and methanogens predominate more distally where hydrogen concentration is considerably lower. Leadbetter et al. (1999) discovered that the separation is facilitated by the attachment of acetogens to spirochetes resident in the termite gut.
RA in the large intestine has been estimated to provide 0.25% of the energy requirements of rats, rabbits and guinea pigs (Yang et al. 1970; Prins and Lankhorst 1977). Graeve and Demeyer (1990) found circumstantial evidence for the existence of RA in the hindgut of cattle as well as of pigs, and this was confirmed by later in vitro studies (De Graeve et al. 1994). Evans et al. (2009) latterly identified the existence of RA in the foregut of the tamar wallaby (Macropus eugen), whereas in humans, a minority of the population have detectable levels of methanogenic Archaea (MA) (Bernalier et al. 1996) and it appears that MA have a competitively exclusive relationship with acetogenic bacteria (AB) (Doré et al. 1995), a phenomenon also observed in new born lambs (Morvan et al. 1994).
RA have been isolated from ruminants including deer (Rieu-Lesme et al. 1995) and lambs (Rieu-Lesme et al. 1996) as well as cattle (Greening and Leedle 1989). However, attempts to grow acetogens in mixed culture in vitro have only been possible using partial pressures of hydrogen far above that encountered in a normally functioning rumen, or chemical suppression of methanogens, or both, to be successful (Nollet et al. 1997; le Van et al. 1998; Nollet et al. 1998; Lopez et al. 1999). Early attempts to induce RA in vivo have been reviewed by Fievez et al. (1999), who concluded that all attempts, even after suppression of MA, were unsuccessful. More recently Fonty et al. (2007) reported successfully establishing and maintaining a population of RA species in gnotobiotic lambs; however, methane production was not recorded and hydrogen production and utilisation were estimated indirectly from volatile fatty acids (VFA) stoichiometry. The study concluded that methanogens increased quickly to normal densities when they were introduced to the rumen of acetogen-colonised lambs.
It appears that the critical requirement for RA to establish as a significant metabolic process in the rumen is a high partial pressure of hydrogen (Weimer 1998). Further, evidence suggests RA cannot occur in the rumen unless MA are permanently suppressed, with unknown consequences for the host animal. Thus, it appears that because MA have such a high affinity for hydrogen, the likelihood of RA being a substantial hydrogen sink, thus reducing production of methane in the rumen is low.
Defaunation
Elimination of protozoa from the rumen (defaunation) has been the subject of considerable interest and investigation over the last 50 years. Although ubiquitous, ciliate protozoa are not essential to proper functioning of the rumen, and it was suggested that their absence may lead to improved production efficiency (BRYANT 1970). Trials undertaken to assess the effect of defaunation on animal productivity have generally shown that growth, and in particular wool growth in sheep, improves, especially where rumen bypass protein is limited (Bird and Leng 1978; Bird et al. 1979; Eugène et al. 2004b) From a meta-analysis of defaunation trials it was concluded that although feed digestibility was lower in defaunated sheep, there were substantial increases in microbial nitrogen outflow with a concomitant decrease in rumen ammonia concentration (Eugène et al. 2004a) and such changes are consistent with the notion that elimination of protozoa would diminish wasteful lysis and intraruminal recycling of bacteria.
Protozoa do not possess H+-utilising (i.e. propiogenic) metabolic pathways, and many methanogens form a close physical and probably symbiotic relationship with ciliates (Chagan et al. 1999). This has led to the suggestion that defaunation may be an effective strategy to reduce enteric methane production (Hegarty 1999). There is some evidence that defaunation decreases methane production in sheep (Kreuzer et al. 1986) and cattle (Whitelaw et al. 1984). Overall the evidence is equivocal, if not contradictory and the effect of defaunation on enteric methane production not clear, with Bird et al. (2008) failing to find differences in methane production between faunated and defaunated ewes at 10 and 25 weeks after treatment. In studies using medium chain fatty acids (MCFA) to suppress protozoa in sheep (Machmüller et al. 2000, 2003) the authors attributed the decrease in methane to MCFA’s inhibitory effect on methanogens themselves, as well as reducing protozoa. A definitive study of lambs born fauna-free to previously chemically defaunated ewes, Hegarty et al. (2008) found no difference in enteric methane production between faunated and fauna-free animals. Thus, it appears that although substantial gains in productivity may be realised through the defaunation of ruminants, decreasing energy losses through the diminution of enteric methane production, does not appear to form part of those gains.
Host response: immunisation
Early trials by researchers in Western Australia produced two vaccines designed to induce an immune response to rumen methanogens (Wright et al. 2004). Plasma IgA and IgB antibodies titres in sheep showed a significant response post-immunisation. However, extensive testing and repeated applications of the vaccines failed to produce significant reductions in methane production (P-value 0.401–0.751), except on one occasion where a 7.7% decrease of CH4 per unit dry matter intake (DMI) (P = 0.051) was observed. A vaccine prepared on a similar principle (i.e. using cell extracts from the target species) with the aim of reducing rumen protozoa (Williams et al. 2008), showed little response, as did a vaccine based on five phylotypes of methanogens (Williams et al. 2009), suggesting approaches based on a limited number of species of methanogens is unlikely to be effective.
Both Attwood et al. (2011) and Wedlock et al. (2013) have emphasised the importance of developing an effective methanogen vaccine that targets all methanogens, to prevent non-target species expanding to fill the ecological niches left by those selectively eliminated, while avoiding affecting non-target organisms. This will require the identification of some common features, such as a shared surface protein, unique to Archaea, so as not to interfere with or compromise the function of other bacterial consortia playing crucial roles in ruminal digestion. Recent trials using a recombinant protein as a potential antigen against methanogens elicited strong antibody responses in both cattle (Subharat et al. 2015) and sheep (Subharat et al. 2016), but neither study quantified rumen methanogens or enteric methane production post-immunisation. Using a different protein, but employing a similar approach, Zhang et al. (2015) also observed strong immune responses in saliva and plasma, yet failed to detect any reduction in either rumen methanogens or enteric methane production in inoculated goats. It is concluded that although conceptually appealing, work to date has produced very little actual evidence for the efficacy of methanogen vaccines on the production of enteric methane in vivo.
Host response: early life programming (ELP)
The influence of diet during early life on the bacterial community (Eadie et al. 1959) and physical structure of the rumen (Greenwood et al. 1997) is well recognised. This interrelationship has led to speculation that dietary or other interventions during early life might be able to influence the life-time microbial community of ruminants (Morvan et al. 1994) and thus affect life-time methane production. Abecia et al. (2013, 2014) explored the effect of ELP on enteric methane production in lambs using bromochloromethane to suppress methanogens in new-born lambs and their dams, but reported that the reduction in methane production lasted only as long as treatment persisted, although noting a longer term change in the archaeal community. In contrast, De Barbieri et al. (2015a) observed persistent changes in the rumen microbial community of lambs inoculated with rumen content from different sources; however, this did not translate into differences in enteric methane production (De Barbieri et al. 2015b). This approach appears to have some promise, but it is clear our understanding of effects and modalities of ELP are at a preliminary stage (Yáñez-Ruiz et al. 2015) and there are no practical applications to reduce enteric methane at present.
Conclusion
There are several potential modalities available to reduce enteric methane emissions by altering the rumen population through extraneous means. Although initially promising, after extensive testing it seems clear that the introduction of reductive acetogens and elimination of ciliates will not produce the desired effect. Although attempts are still ongoing, there has been a similar lack of success in producing an effective methanogen vaccine and understanding of ELP is still at a preliminary stage. Thus it is concluded that at present there are no demonstrated technologies that will reduce enteric methane by altering the rumen biome in an enduring manner.
Changing the animal: the low-methane phenotype
Substantial differences in methane production have been observed between animals consuming the same quantity of a given diet (Blaxter and Clapperton 1965; Lassey et al. 1997; Ulyatt et al. 1999; Hegarty et al. 2007). There is evidence to indicate that digestibility of feed is inversely related to methane production per unit intake (e.g. (Gordon et al. 1995; Yan et al. 2000), although intake and digestibility are frequently conflated in the literature. In any case, these factors fail to explain why animals under identical conditions should have different methane yields (MY; gCH4/MJ of digestible energy intake). Observed differences between animals in MY under equivalent conditions may be due to differences in the animals’ digestive physiology, in the rumen microbial community, or a combination of both. Partially shifting the site of digestion, or alterations in the bacterial and ciliate populations each have the capacity to change the amount of methane generated per unit of energy ingested through changing the amount and profile of VFA, the partitioning of energy between cell growth and maintenance, and ultimately the amount of hydrogen generated. The extent to which each of these factors are important in determining between-animal differences in MY, and the degree to which they are labile to manipulation will determine the theoretical potential of developing a ‘low methane phenotype’ (LMP) animal.
Contribution of digestive physiology
Residence time of digesta, along with composition of the microbial population, may each be influenced by mean (rumen) retention time (MRT). Although level of food intake is negatively correlated with MRT (Grovum and Williams 1973; Evans 1981), voluntary feed intake is positively related to rate of eating (Forbes et al. 1972), which is itself highly repeatable among diets and over time for individual animals, but is highly variable between individual animals (Frisch and Vercoe 1977). So it can be deduced that individual variation in rate of eating may be expressed in differing MRT and it has also been demonstrated that whole tract digesta time varies more between animals than for individuals across diets (Bines and Davey 1970). Thus, variables directly under the control of the animal will affect important facets of digestive physiology in the ruminant, but the case for digestive physiology having a direct impact on MY goes well beyond intake and rate of eating.
The evidence for MRT and associated rumen parameters being a significant determinant of MY is quite compelling. Okine et al. (1989) found cattle with weights in their rumens produced 29% less methane than control animals fed the same amount of the same diet and that methane production was inversely correlated (r = –0.53) with outflow of rumen particulate matter. Similarly, Smuts et al. (1995) demonstrated that sheep selected for high wool growth had higher rumen outflows and consequently, higher microbial outflow from the rumen than low-wool growth sheep. Pinares-Patiño et al. (2003) observed that rumen outflow rate accounted for ~57% of the difference in MY in sheep fed a restricted diet (1.3 times maintenance), whereas Barnett et al. (2012) clearly demonstrated that manipulating gut motility and reducing transit time would decrease MY in sheep at a given intake. The critical role of rumen digestion parameters in determining enteric methane production has been confirmed in studies using previously identified low MY (LMY) and high MY (HMY) sheep., where LMY was strongly associated with not only decreased MRT in both solid and liquid phases, but also smaller rumen volume and differences in rumen contents (Goopy et al. 2014; Bond et al. 2017). Daily Methane Production and more recently, MY have been shown to have a low but significant heritability (h2 = 0.13) with distinct sire differences and so there is scope for genetic selection (Robinson et al. 2010; Pinares-Patiño et al. 2011, 2013). Because MY is a complex trait that is technically challenging to measure, discovering the mechanism(s) by which animal genotype affects MY may help in the identification of proxies which are indicative of MY. This is consistent with the findings reported by Barnett et al. (2012), who demonstrated that a reduction in whole-tract MRT (induced by injections of triiodothyronine every second day) also reduced MY, identifying the possibility that blood triiodothyronine concentration may be a factor by which animal genotype affects MRT and so a possible indicator of proxies for MY. To this end, Clauss and Hummel (2017) suggested that selective breeding of ruminants for increased liquid digesta flow rates is likely to be an efficacious strategy to reduce MY, although how this might be undertaken in practical terms, is not addressed. Although it is yet to be investigated empirically, a final consideration is the possible impact of selection for LMY on animal productivity. If decreased rumen volume and MRT are the physiological drivers for LMY, it may be posited that to select for LMY will diminish an animal’s ability to assimilate nutrients from low-quality roughages frequently encountered under rangeland conditions, with potentially deleterious effects.
Contribution of microbial genomics
Meng et al. (1999) demonstrated in vitro that increasing dilution rates were associated with improved microbial efficiency and increased VFA concentrations, while lowering ammonia concentrations in rumen fluid. By quantifying rRNA, Weimer (1998) determined that there were differences up to 8-fold in relative abundance of the three main cellulolytic species between a small number of cattle consuming the same ad libitum diets. Chen and Weimer (2001) have demonstrated in vitro that varying dilution rates in continuous cultures has substantial effects on the relative abundance of key cellulolytic and amyolytic bacteria. Studies using PCR–DDGE have identified clear differences in microbial communities of steers selected for divergent feed efficiency (Guan et al. 2008), indicating clear interrelationships between rumen microbial population structure and host physiology. Thus, evidence for a nexus between LMP animals and differentiated microbial communities, is mounting.
Kittelmann et al. (2014) found two distinctly different rumen bacterial communities in LMY sheep, and suggested that the predominant metabolic pathways used by the main species in the communities would result in the production of lower levels of H+. Separately, Shi et al. (2014) discovered that gene pathways involved in methanogenesis were differentially expressed in high and low MY sheep, even though total numbers of methanogens did not differ. In contrast, Wallace et al. (2015), using a metagenomics approach to explore rumen microbial community difference in LMY and HMY cattle, reported a much greater abundance of methanogens in HMY cattle, and observed similar differences in methanogenic gene expression between groups.
More recently, employing 16S rRNA gene amplicon sequencing from previously identified HMY and LMY sheep, Kamke et al. (2016) found increased lactate-producing Sharpea spp. in LMY sheep bacterial communities, suggesting that the rumen microbiome in LMY animals support increased lactate production, which in turn, is metabolised to butyrate, resulting in a significantly reduced yield of hydrogen ions. Moreover, the authors of this study concluded that the observed differences in the LMY microbial community are consistent with the hypothesis that a smaller rumen size with a higher turnover rate, (where rapid heterofermentative growth would be an advantage) results in lower H+ production and lower methane formation, thus explicitly making the link between host digestive anatomy/physiology and the differentiated rumen biome.
Conclusion
There is strong evidence for the existence of a LMP animal in both bovine and ovine populations. However, as studies by Münger and Kreuzer (2008), and more recently, Duthie et al. (2017) have shown, such differences are unlikely to conveniently fall along existing breed lines, but individuals with LMP will need to be identified through rigorous and technically challenging testing of a general population. At present, the ‘gold standard’ method for identifying individuals with LMY or HMY is measurement under standardised conditions in open-circuit respiratory chambers, which is expensive, laborious and time-consuming. Simpler procedures, using short-term measurements have been developed (Goopy et al. 2009, 2011), but are less sensitive and require a greater number of measurements to be useful (Pickering et al. 2015). Recent research suggests there is possibly a strong association between particular rumen microbial communities and the physiological/anatomical characteristics of a LMP animal, but this is yet to be conclusively demonstrated. If proven, rumen microbial profiling may provide a long-sought after proxy for identifying LMP animals, but even then testing will most likely need to include the provision of standardised feeding conditions.
Creating the LMP ruminant
It can be said there are two broad approaches to creating the LMP ruminant. The first is to alter the rumen enduringly through exogenous means. This has the attraction of being able to be applied to any and all animals in a population, and would achieve an immediate, one-off decrease in enteric methane emissions, but unfortunately the evidence to date for being able to achieve such a feat is disappointingly lacking. The second approach is that of identifying individuals within the population who possess the desired phenotype, then selecting for those animals. In the case of the LMP, it needs to be considered that: (1) the technical requirements for identifying and testing animals are prodigious; (2) the differences between identified LMY and HMY animals are only in the region of 12–15% (Goopy et al. 2014; Kittelmann et al. 2014) and there is no evidence that this will be increased through trait selection; and (3) there is little if any, economic benefit to be gained by farmers in selecting for LMP under prevailing economic conditions (Robinson and Oddy 2016). Further, Eckard et al. (2010) has warned that even though genetic selection for LMP animals is theoretically possible, the rate of genetic gain for the trait will necessarily be low in any multi-trait breeding program.
Thus, on the basis of current understanding, LMP animals can be identified, albeit with some difficulty. Animals that express the trait produce 6–8% less methane on a given diet (Goopy et al. 2014; Kittelmann et al. 2014) than the general population. The trait is heritable, but not highly so, and might or might not be more fully expressed over subsequent generations of animals selected for the trait. In any case, such a breeding program would require considerable resources to establish and significant industry participation to be successful over many years – and this in an environment where there is no economic imperative to do so.
In contrast, there are at present, a number of practicable, implementable and financially beneficial management options for ruminant productions systems that will almost immediately reduce enteric methane emissions intensities 2–13% (Alcock and Hegarty 2006). In more industrialised livestock systems where the scope to reduce emissions intensities through improved nutrition, husbandry or health becomes narrower, genetic selection, along with dietary additives, may be the only future options. However in developing, low-intensity production systems where emissions intensities for livestock systems can be reduced by 30% or more (J. Goopy, unpubl. data) by simple dietary interventions that increase productivity, it seems questionable as to whether development of the LMP animal is the first, best, choice.
Conflicts of interest
The author declares no conflicts of interest.
Acknowledgements
This work was conducted as part of the CGIAR Research Program on Livestock, which is supported by contributors to the CGIAR Trust Fund. CGIAR is a global research partnership for a food-secure future. Its science is carried out by 15 research centres in close collaboration with hundreds of partners across the globe (www.cgiar.org).
References
Abecia L, Waddams KE, Martínez-Fernandez G, Martín-García AI, Ramos-Morales E, Newbold J, Yáñez-Ruiz DR (2014) An antimethanogenic nutritional intervention in early life of ruminants modifies ruminal colonization by Archaea. Archaea 2014, 841463| An antimethanogenic nutritional intervention in early life of ruminants modifies ruminal colonization by Archaea.Crossref | GoogleScholarGoogle Scholar | 24803846PubMed |
Abecia L, Martín-García AI, Martínez G, Newbold CJ, Yáñez-Ruiz DR (2013) Nutritional intervention in early life to manipulate rumen microbial colonization and methane output by kid goats postweaning1. Journal of Animal Science 91, 4832–4840.
| Nutritional intervention in early life to manipulate rumen microbial colonization and methane output by kid goats postweaning1.Crossref | GoogleScholarGoogle Scholar | 23965388PubMed |
Alcock D, Hegarty RS (2006) Effects of pasture improvement on productivity, gross margin and methane emissions of a grazing sheep enterprise. International Congress Series 1293, 103–106.
| Effects of pasture improvement on productivity, gross margin and methane emissions of a grazing sheep enterprise.Crossref | GoogleScholarGoogle Scholar |
Attwood GT, Altermann E, Kelly WJ, Leahy SC, Zhang L, Morrison M (2011) Exploring rumen methanogen genomes to identify targets for methane mitigation strategies. Animal Feed Science and Technology 166–167, 65–75.
| Exploring rumen methanogen genomes to identify targets for methane mitigation strategies.Crossref | GoogleScholarGoogle Scholar |
Barnett M, Goopy J, McFarlane J, Godwin I, Nolan J, Hegarty R (2012) Triiodothyronine influences digesta kinetics and methane yield in sheep. Animal Production Science 52, 572–577.
| Triiodothyronine influences digesta kinetics and methane yield in sheep.Crossref | GoogleScholarGoogle Scholar |
Beauchemin KA, Kreuzer M, O’Mara F, McAllister TA (2008) Nutritional management for enteric methane abatement: a review. Australian Journal of Experimental Agriculture 48, 21–27.
| Nutritional management for enteric methane abatement: a review.Crossref | GoogleScholarGoogle Scholar |
Bernalier A, Lelait M, Rochet V, Grivet J-P, Gibson GR, Durand M (1996) Acetogenesis from H2 and CO2 by methane- and non-methane-producing human colonic bacterial communities. FEMS Microbiology Ecology 19, 193–202.
| Acetogenesis from H2 and CO2 by methane- and non-methane-producing human colonic bacterial communities.Crossref | GoogleScholarGoogle Scholar |
Bines JA, Davey AWF (1970) Voluntary intake, digestion, rate of passage, amount of material in the alimentary tract and behaviour in cows receiving complete diets containing straw and concentrates in different proportions. British Journal of Nutrition 24, 1013–1028.
| Voluntary intake, digestion, rate of passage, amount of material in the alimentary tract and behaviour in cows receiving complete diets containing straw and concentrates in different proportions.Crossref | GoogleScholarGoogle Scholar | 5484722PubMed |
Bird SH, Leng RA (1978) The effects of defaunation of the rumen on the growth of cattle on low-protein high-energy diets. British Journal of Nutrition 40, 163–167.
| The effects of defaunation of the rumen on the growth of cattle on low-protein high-energy diets.Crossref | GoogleScholarGoogle Scholar | 667001PubMed |
Bird SH, Hill MK, Leng RA (1979) The effects of defaunation of the rumen on the growth of lambs on low-protein-high-energy diets. British Journal of Nutrition 42, 81–87.
| The effects of defaunation of the rumen on the growth of lambs on low-protein-high-energy diets.Crossref | GoogleScholarGoogle Scholar | 486396PubMed |
Bird SH, Hegarty RS, Woodgate R (2008) Persistence of defaunation effects on digestion and methane production in ewes. Australian Journal of Experimental Agriculture 48, 152–155.
| Persistence of defaunation effects on digestion and methane production in ewes.Crossref | GoogleScholarGoogle Scholar |
Blaxter K, Clapperton J (1965) Prediction of the amount of methane produced by ruminants. British Journal of Nutrition 19, 511–522.
| Prediction of the amount of methane produced by ruminants.Crossref | GoogleScholarGoogle Scholar | 5852118PubMed |
Bond JJ, Cameron M, Donaldson AJ, Austin KL, Harden S, Robinson DL, Oddy VH (2017) Aspects of digestive function in sheep related to phenotypic variation in methane emissions. Animal Production Science 59, 55–65.
| Aspects of digestive function in sheep related to phenotypic variation in methane emissions.Crossref | GoogleScholarGoogle Scholar |
Breznak JA, Kane MD (1990) Microbial H2/CO2 acetogenesis in animal guts: nature and nutritional significance. FEMS Microbiology Letters 87, 309–313.
| Microbial H2/CO2 acetogenesis in animal guts: nature and nutritional significance.Crossref | GoogleScholarGoogle Scholar |
Bryant MP (1970) Normal flora – rumen bacteria. American Journal of Clinical Nutrition 23, 1440–1450.
| Normal flora – rumen bacteria.Crossref | GoogleScholarGoogle Scholar | 4920104PubMed |
Chagan I, Tokura M, Jouany J-P, Ushida K (1999) Detection of methanogenic archaea associated with rumen ciliate protozoa. Journal of General and Applied Microbiology 45, 305–308.
| Detection of methanogenic archaea associated with rumen ciliate protozoa.Crossref | GoogleScholarGoogle Scholar | 12501361PubMed |
Chen J, Weimer PJ (2001) Competition among three predominant ruminal cellulolytic bacteria in the absence or presence of non-cellulolytic bacteria. Microbiology 147, 21–30.
| Competition among three predominant ruminal cellulolytic bacteria in the absence or presence of non-cellulolytic bacteria.Crossref | GoogleScholarGoogle Scholar | 11160797PubMed |
Clauss M, Hummel J (2017) Physiological adaptations of ruminants and their potential relevance for production systems. Revista Brasileira de Zootecnia 46, 606–613.
| Physiological adaptations of ruminants and their potential relevance for production systems.Crossref | GoogleScholarGoogle Scholar |
Cord-Ruwisch R, Seitz H-J, Conrad R (1988) The capacity of hydrogenotrophic anaerobic bacteria to compete for traces of hydrogen depends on the redox potential of the terminal electron acceptor. Archives of Microbiology 149, 350–357.
| The capacity of hydrogenotrophic anaerobic bacteria to compete for traces of hydrogen depends on the redox potential of the terminal electron acceptor.Crossref | GoogleScholarGoogle Scholar |
De Barbieri I, Hegarty RS, Silveira C, Gulino LM, Oddy VH, Gilbert RA, Klieve AV, Ouwerkerk D (2015a) Programming rumen bacterial communities in newborn Merino lambs. Small Ruminant Research 129, 48–59.
| Programming rumen bacterial communities in newborn Merino lambs.Crossref | GoogleScholarGoogle Scholar |
De Barbieri I, Hegarty RS, Silveira C, Oddy VH (2015b) Positive consequences of maternal diet and post-natal rumen inoculation on rumen function and animal performance of Merino lambs. Small Ruminant Research 129, 37–47.
| Positive consequences of maternal diet and post-natal rumen inoculation on rumen function and animal performance of Merino lambs.Crossref | GoogleScholarGoogle Scholar |
De Graeve KG, Grivet JP, Durand M, Beaumatin P, Cordelet C, Hannequart G, Demeyer D (1994) Competition between reductive acetogenesis and methanogenesis in the pig large-intestinal flora. Journal of Applied Bacteriology 76, 55–61.
| Competition between reductive acetogenesis and methanogenesis in the pig large-intestinal flora.Crossref | GoogleScholarGoogle Scholar | 8144406PubMed |
Denman SE, Tomkins NW, McSweeney CS (2007) Quantitation and diversity analysis of ruminal methanogenic populations in response to the antimethanogenic compound bromochloromethane. FEMS Microbiology Ecology 62, 313–322.
| Quantitation and diversity analysis of ruminal methanogenic populations in response to the antimethanogenic compound bromochloromethane.Crossref | GoogleScholarGoogle Scholar | 17949432PubMed |
Doré J, Pochart P, Bernalier A, Goderel I, Morvan B, Rambaud JC (1995) Enumeration of H2-utilizing methanogenic archaea, acetogenic and sulfate-reducing bacteria from human feces. FEMS Microbiology Ecology 17, 279–284.
| Enumeration of H2-utilizing methanogenic archaea, acetogenic and sulfate-reducing bacteria from human feces.Crossref | GoogleScholarGoogle Scholar |
Duthie CA, Haskell M, Hyslop JJ, Waterhouse A, Wallace RJ, Roehe R, Rooke JA (2017) The impact of divergent breed types and diets on methane emissions, rumen characteristics and performance of finishing beef cattle. animal 11, 1762–1771.
| The impact of divergent breed types and diets on methane emissions, rumen characteristics and performance of finishing beef cattle.Crossref | GoogleScholarGoogle Scholar | 28222832PubMed |
Eadie JM, Hobson P, Mann S (1959) A relationship between some bacteria, protozoa and diet in early weaned calves. Nature 183, 624–625.
| A relationship between some bacteria, protozoa and diet in early weaned calves.Crossref | GoogleScholarGoogle Scholar | 13632819PubMed |
Eckard RJ, Grainger C, de Klein CAM (2010) Options for the abatement of methane and nitrous oxide from ruminant production: a review. Livestock Science 130, 47–56.
| Options for the abatement of methane and nitrous oxide from ruminant production: a review.Crossref | GoogleScholarGoogle Scholar |
Eugène M, Archimède H, Sauvant D (2004a) Quantitative meta-analysis on the effects of defaunation of the rumen on growth, intake and digestion in ruminants. Livestock Production Science 85, 81–97.
| Quantitative meta-analysis on the effects of defaunation of the rumen on growth, intake and digestion in ruminants.Crossref | GoogleScholarGoogle Scholar |
Eugène M, Archimède H, Weisbecker J-L, Periacarpin F, Saminadin G, Sauvant D (2004b) Effects of defaunation on digestion and growth, in sheep receiving a mixed diet (fresh Digitaria decumbens grass and concentrate) at four protein to energy ratios. Animal Research 53, 111–125.
| Effects of defaunation on digestion and growth, in sheep receiving a mixed diet (fresh Digitaria decumbens grass and concentrate) at four protein to energy ratios.Crossref | GoogleScholarGoogle Scholar |
Evans E (1981) An evaluation of the relationships between dietary parameters and rumen solid turnover rate. Canadian Journal of Animal Science 61, 97–103.
| An evaluation of the relationships between dietary parameters and rumen solid turnover rate.Crossref | GoogleScholarGoogle Scholar |
Evans PN, Hinds LA, Sly LI, McSweeney CS, Morrison M, Wright A-DG (2009) Community composition and density of methanogens in the foregut of the tammar Wallaby (Macropus eugenii). Applied and Environmental Microbiology 75, 2598–2602.
| Community composition and density of methanogens in the foregut of the tammar Wallaby (Macropus eugenii).Crossref | GoogleScholarGoogle Scholar | 19218421PubMed |
Fievez V, Piattoni F, Mbanzamihigo L, Demeyer D (1999) Reductive acetogenesis in the hindgut and Attempts to its induction in the rumen – a review. Journal of Applied Animal Research 16, 1–22.
| Reductive acetogenesis in the hindgut and Attempts to its induction in the rumen – a review.Crossref | GoogleScholarGoogle Scholar |
Fonty G, Joblin K, Chavarot M, Roux R, Naylor G, Michallon F (2007) Establishment and development of ruminal hydrogenotrophs in methanogen-free lambs. Applied and Environmental Microbiology 73, 6391–6403.
| Establishment and development of ruminal hydrogenotrophs in methanogen-free lambs.Crossref | GoogleScholarGoogle Scholar | 17675444PubMed |
Forbes JM, Wright JA, Bannister A (1972) A note on rate of eating in sheep. Animal Science 15, 211–214.
| A note on rate of eating in sheep.Crossref | GoogleScholarGoogle Scholar |
Frisch JE, Vercoe JE (1977) Food intake, eating rate, weight gains, metabolic rate and efficiency of feed utilization in Bos taurus and Bos indicus crossbred cattle. Animal Science 25, 343–358.
| Food intake, eating rate, weight gains, metabolic rate and efficiency of feed utilization in Bos taurus and Bos indicus crossbred cattle.Crossref | GoogleScholarGoogle Scholar |
Goopy J, Hegarty R, Robinson D (2009) Two hour chamber measurement provides a useful estimate of daily methane production in sheep, ruminant physiology: digestion, metabolism and effects of nutrition on reproduction and welfare. In ‘Proceedings of the XIth International Symposium on Ruminant Physiology, Clermont-Ferrand, France’. (Wageningen Academic Publishers: Wageningen, Germany)
Goopy JP, Woodgate R, Donaldson A, Robinson DL, Hegarty RS (2011) Validation of a short-term methane measurement using portable static chambers to estimate daily methane production in sheep. Animal Feed Science and Technology 166–167, 219–226.
| Validation of a short-term methane measurement using portable static chambers to estimate daily methane production in sheep.Crossref | GoogleScholarGoogle Scholar |
Goopy JP, Donaldson A, Hegarty R, Vercoe PE, Haynes F, Barnett M, Oddy VH (2014) Low-methane yield sheep have smaller rumens and shorter rumen retention time. British Journal of Nutrition 111, 578–585.
| Low-methane yield sheep have smaller rumens and shorter rumen retention time.Crossref | GoogleScholarGoogle Scholar | 24103253PubMed |
Gordon FJ, Porter MG, Mayne CS, Unsworth EF, Kilpatrick DJ (1995) Effect of forage digestibility and type of concentrate on nutrient utilization by lactating dairy cattle. Journal of Dairy Research 62, 15–27.
| Effect of forage digestibility and type of concentrate on nutrient utilization by lactating dairy cattle.Crossref | GoogleScholarGoogle Scholar | 7738241PubMed |
Graeve KD, Demeyer D (1990) Efficiency of short chain fatty acid production in the rumen and hindgut. Mededelingen van de Faculteit Landbouwwetenschappen - Rijksuniversiteit Gent 55, 1499–1504.
Greening RC, Leedle JAZ (1989) Enrichment and isolation of Acetitomaculum ruminis, gen. nov., sp. nov.: acetogenic bacteria from the bovine rumen. Archives of Microbiology 151, 399–406.
| Enrichment and isolation of Acetitomaculum ruminis, gen. nov., sp. nov.: acetogenic bacteria from the bovine rumen.Crossref | GoogleScholarGoogle Scholar | 2500921PubMed |
Greenwood RH, Morrill JL, Titgemeyer EC, Kennedy GA (1997) A new method of measuring diet abrasion and its effect on the development of the forestomach. Journal of Dairy Science 80, 2534–2541.
| A new method of measuring diet abrasion and its effect on the development of the forestomach.Crossref | GoogleScholarGoogle Scholar | 9361226PubMed |
Grovum WL, Williams VJ (1973) Rate of passage of digesta in sheep: 1. The effect of level of food intake on marker retention times along the small intestine and on apparent water absorption in the small and large intestines. British Journal of Nutrition 29, 13–21.
| Rate of passage of digesta in sheep: 1. The effect of level of food intake on marker retention times along the small intestine and on apparent water absorption in the small and large intestines.Crossref | GoogleScholarGoogle Scholar | 4631113PubMed |
Guan LL, Nkrumah JD, Basarab JA, Moore SS (2008) Linkage of microbial ecology to phenotype: correlation of rumen microbial ecology to cattle’s feed efficiency. FEMS Microbiology Letters 288, 85–91.
| Linkage of microbial ecology to phenotype: correlation of rumen microbial ecology to cattle’s feed efficiency.Crossref | GoogleScholarGoogle Scholar | 18785930PubMed |
Hegarty RS (1999) Reducing rumen methane emissions through elimination of rumen protozoa. Australian Journal of Agricultural Research 50, 1321–1328.
| Reducing rumen methane emissions through elimination of rumen protozoa.Crossref | GoogleScholarGoogle Scholar |
Hegarty RS, Goopy JP, Herd RM, McCorkell B (2007) Cattle selected for lower residual feed intake have reduced daily methane production. Journal of Animal Science 85, 1479–1486.
| Cattle selected for lower residual feed intake have reduced daily methane production.Crossref | GoogleScholarGoogle Scholar | 17296777PubMed |
Hegarty RS, Bird SH, Vanselow BA, Woodgate R (2008) Effects of the absence of protozoa from birth or from weaning on the growth and methane production of lambs. British Journal of Nutrition 100, 1220–1227.
| Effects of the absence of protozoa from birth or from weaning on the growth and methane production of lambs.Crossref | GoogleScholarGoogle Scholar | 18479584PubMed |
Hegarty R, Alcock D, Robinson D, Goopy J, Vercoe P (2010) Nutritional and flock management options to reduce methane output and methane per unit product from sheep enterprises. Animal Production Science 50, 1026–1033.
| Nutritional and flock management options to reduce methane output and methane per unit product from sheep enterprises.Crossref | GoogleScholarGoogle Scholar |
Iqbal MF, Cheng Y-F, Zhu W-Y, Zeshan B (2008) Mitigation of ruminant methane production: current strategies, constraints and future options. World Journal of Microbiology & Biotechnology 24, 2747–2755.
| Mitigation of ruminant methane production: current strategies, constraints and future options.Crossref | GoogleScholarGoogle Scholar |
Joblin KN (1999) Ruminal acetogens and their potential to lower ruminant methane emissions. Australian Journal of Agricultural Research 50, 1307–1314.
| Ruminal acetogens and their potential to lower ruminant methane emissions.Crossref | GoogleScholarGoogle Scholar |
Jones RJ, Megarrity RG (1986) Successful transfer of DHP-degrading bacteria from Hawaiian goats to Australian ruminants to overcome the toxicity of Leucaena. Australian Veterinary Journal 63, 259–262.
| Successful transfer of DHP-degrading bacteria from Hawaiian goats to Australian ruminants to overcome the toxicity of Leucaena.Crossref | GoogleScholarGoogle Scholar | 3790013PubMed |
Kamke J, Kittelmann S, Soni P, Li Y, Tavendale M, Ganesh S, Janssen PH, Shi W, Froula J, Rubin EM (2016) Rumen metagenome and metatranscriptome analyses of low methane yield sheep reveals a Sharpea-enriched microbiome characterised by lactic acid formation and utilisation. Microbiome 4, 56
| Rumen metagenome and metatranscriptome analyses of low methane yield sheep reveals a Sharpea-enriched microbiome characterised by lactic acid formation and utilisation.Crossref | GoogleScholarGoogle Scholar | 27760570PubMed |
Kittelmann S, Pinares-Patiño CS, Seedorf H, Kirk MR, Ganesh S, McEwan JC, Janssen PH (2014) Two different bacterial community types are linked with the low-methane emission trait in sheep. PLoS One 9, e103171
| Two different bacterial community types are linked with the low-methane emission trait in sheep.Crossref | GoogleScholarGoogle Scholar | 25383707PubMed |
Kreuzer M, Kirchgessner M, Müller HL (1986) Effect of defaunation on the loss of energy in wethers fed different quantities of cellulose and normal or steamflaked maize starch. Animal Feed Science and Technology 16, 233–241.
| Effect of defaunation on the loss of energy in wethers fed different quantities of cellulose and normal or steamflaked maize starch.Crossref | GoogleScholarGoogle Scholar |
Kumar S, Choudhury PK, Carro MD, Griffith GW, Dagar SS, Puniya M, Calabro S, Ravella SR, Dhewa T, Upadhyay RC, Sirohi SK, Kundu SS, Wanapat M, Puniya AK (2014) New aspects and strategies for methane mitigation from ruminants. Applied Microbiology and Biotechnology 98, 31–44.
| New aspects and strategies for methane mitigation from ruminants.Crossref | GoogleScholarGoogle Scholar | 24247990PubMed |
Lassey KR, Ulyatt MJ, Martin RJ, Walker CF, David Shelton I (1997) Methane emissions measured directly from grazing livestock in New Zealand. Atmospheric Environment 31, 2905–2914.
| Methane emissions measured directly from grazing livestock in New Zealand.Crossref | GoogleScholarGoogle Scholar |
le Van TD, Robinson JA, Ralph J, Greening RC, Smolenski WJ, Leedle JAZ, Schaefer DM (1998) Assessment of reductive acetogenesis with indigenous ruminal bacterium populations and Acetitomaculum ruminis. Applied and Environmental Microbiology 64, 3429–3436.
Leadbetter JR, Schmidt TM, Graber JR, Breznak JA (1999) Acetogenesis from H2 plus CO2 by spirochetes from termite guts. Science 283, 686–689.
| Acetogenesis from H2 plus CO2 by spirochetes from termite guts.Crossref | GoogleScholarGoogle Scholar | 9924028PubMed |
Leng RA (2018) Unravelling methanogenesis in ruminants, horses and kangaroos: the links between gut anatomy, microbial biofilms and host immunity. Animal Production Science 58, 1175–1191.
| Unravelling methanogenesis in ruminants, horses and kangaroos: the links between gut anatomy, microbial biofilms and host immunity.Crossref | GoogleScholarGoogle Scholar |
Lopez S, McIntosh FM, Wallace RJ, Newbold CJ (1999) Effect of adding acetogenic bacteria on methane production by mixed rumen microorganisms. Animal Feed Science and Technology 78, 1–9.
| Effect of adding acetogenic bacteria on methane production by mixed rumen microorganisms.Crossref | GoogleScholarGoogle Scholar |
Lovley DR, Klug MJ (1983) Sulfate reducers can outcompete methanogens at freshwater sulfate concentrations. Applied and Environmental Microbiology 45, 187–192.
Machmüller A, Ossowski DA, Kreuzer M (2000) Comparative evaluation of the effects of coconut oil, oilseeds and crystalline fat on methane release, digestion and energy balance in lambs. Animal Feed Science and Technology 85, 41–60.
| Comparative evaluation of the effects of coconut oil, oilseeds and crystalline fat on methane release, digestion and energy balance in lambs.Crossref | GoogleScholarGoogle Scholar |
Machmüller A, Soliva CR, Kreuzer M (2003) Effect of coconut oil and defaunation treatment on methanogenesis in sheep. Reproduction, Nutrition, Development 43, 41–55.
| Effect of coconut oil and defaunation treatment on methanogenesis in sheep.Crossref | GoogleScholarGoogle Scholar | 12785449PubMed |
Meng Q, Kerley MS, Ludden PA, Belyea RL (1999) Fermentation substrate and dilution rate interact to affect microbial growth and efficiency. Journal of Animal Science 77, 206–214.
| Fermentation substrate and dilution rate interact to affect microbial growth and efficiency.Crossref | GoogleScholarGoogle Scholar | 10064046PubMed |
Mitsumori M, Sun W (2008) Control of rumen microbial fermentation for mitigating methane emissions from the rumen. Asian-Australasian Journal of Animal Sciences 21, 144
| Control of rumen microbial fermentation for mitigating methane emissions from the rumen.Crossref | GoogleScholarGoogle Scholar |
Morvan B, Dore J, Rieu-Lesme F, Foucat L, Fonty G, Gouet P (1994) Establishment of hydrogen-utilizing bacteria in the rumen of the newborn lamb. FEMS Microbiology Letters 117, 249–256.
| Establishment of hydrogen-utilizing bacteria in the rumen of the newborn lamb.Crossref | GoogleScholarGoogle Scholar | 8200502PubMed |
Münger A, Kreuzer M (2008) Absence of persistent methane emission differences in three breeds of dairy cows. Animal Production Science 48, 77–82.
| Absence of persistent methane emission differences in three breeds of dairy cows.Crossref | GoogleScholarGoogle Scholar |
Nollet L, Demeyer D, Verstraete W (1997) Effect of 2-bromoethanesulfonic acid and Peptostreptococcus productus ATCC 35244 addition on stimulation of reductive acetogenesis in the ruminal ecosystem by selective inhibition of methanogenesis. Applied and Environmental Microbiology 63, 194–200.
Nollet L, Mbanzamihigo L, Demeyer D, Verstraete W (1998) Effect of the addition of Peptostreptococcus productus ATCC 35244 on reductive acetogenesis in the ruminal ecosystem after inhibition of methanogenesis by cell-free supernatant of Lactobacillus plantarum 80. Animal Feed Science and Technology 71, 49–66.
| Effect of the addition of Peptostreptococcus productus ATCC 35244 on reductive acetogenesis in the ruminal ecosystem after inhibition of methanogenesis by cell-free supernatant of Lactobacillus plantarum 80.Crossref | GoogleScholarGoogle Scholar |
Okine E, Mathison G, Hardin R (1989) Effects of changes in frequency of reticular contractions on fluid and particulate passage rates in cattle 1. Journal of Animal Science 67, 3388–3396.
| Effects of changes in frequency of reticular contractions on fluid and particulate passage rates in cattle 1.Crossref | GoogleScholarGoogle Scholar | 2613584PubMed |
Pickering NK, Oddy VH, Basarab J, Cammack K, Hayes B, Hegarty RS, Lassen J, McEwan JC, Miller S, Pinares-Patiño CS, de Haas Y (2015) Animal board invited review: genetic possibilities to reduce enteric methane emissions from ruminants. animal 9, 1431–1440.
| Animal board invited review: genetic possibilities to reduce enteric methane emissions from ruminants.Crossref | GoogleScholarGoogle Scholar | 26055577PubMed |
Pinares-Patiño CS, Baumont R, Martin C (2003) Methane emissions by Charolais cows grazing a monospecific pasture of timothy at four stages of maturity. Canadian Journal of Animal Science 83, 769–777.
| Methane emissions by Charolais cows grazing a monospecific pasture of timothy at four stages of maturity.Crossref | GoogleScholarGoogle Scholar |
Pinares-Patiño CS, McEwan JC, Dodds KG, Cárdenas EA, Hegarty RS, Koolaard JP, Clark H (2011) Repeatability of methane emissions from sheep. Animal Feed Science and Technology 166–167, 210–218.
| Repeatability of methane emissions from sheep.Crossref | GoogleScholarGoogle Scholar |
Pinares-Patiño CS, Hickey SM, Young EA, Dodds KG, MacLean S, Molano G, Sandoval E, Kjestrup H, Harland R, Hunt C, Pickering NK, McEwan JC (2013) Heritability estimates of methane emissions from sheep. animal 7, 316–321.
| Heritability estimates of methane emissions from sheep.Crossref | GoogleScholarGoogle Scholar | 23739473PubMed |
Prins RA, Lankhorst A (1977) Synthesis of acetate from CO2 in the cecum of some rodents. FEMS Microbiology Letters 1, 255–258.
| Synthesis of acetate from CO2 in the cecum of some rodents.Crossref | GoogleScholarGoogle Scholar |
Rieu-Lesme F, Fonty G, Doré J (1995) Isolation and characterization of a new hydrogen-utilizing bacterium from the rumen. FEMS Microbiology Letters 125, 77–82.
| Isolation and characterization of a new hydrogen-utilizing bacterium from the rumen.Crossref | GoogleScholarGoogle Scholar | 7867923PubMed |
Rieu-Lesme F, Morvan B, Collins MD, Fonty G, Willems A (1996) A new H2CO2-using acetogenic bacterium from the rumen: description of Ruminococcus schinkii sp. nov. FEMS Microbiology Letters 140, 281–286.
Robinson DL, Oddy VH (2016) Benefits of including methane measurements in selection strategies. Journal of Animal Science 94, 3624–3635.
| Benefits of including methane measurements in selection strategies.Crossref | GoogleScholarGoogle Scholar | 27898913PubMed |
Robinson D, Goopy J, Hegarty R, Vercoe P (2010) Repeatability, animal and sire variation in 1-hr methane emissions and relationships with rumen volatile fatty acid concentrations. In ‘Proceedings of the world congress on genetics applied to livestock production’. Available at: http://www.kongressband.de/wcgalp2010/assets/pdf/0712.pdf [Verified 1 November 2010]
Rojas-Downing MM, Nejadhashemi AP, Harrigan T, Woznicki SA (2017) Climate change and livestock: Impacts, adaptation, and mitigation. Climate Risk Management 16, 145–163.
| Climate change and livestock: Impacts, adaptation, and mitigation.Crossref | GoogleScholarGoogle Scholar |
Sabaté J, Soret S (2014) Sustainability of plant-based diets: back to the future. American Journal of Clinical Nutrition 100, 476S–482S.
| Sustainability of plant-based diets: back to the future.Crossref | GoogleScholarGoogle Scholar | 24898222PubMed |
Schmitt-Wagner D, Brune A (1999) Hydrogen profiles and localization of methanogenic activities in the highly compartmentalized hindgut of soil-feeding higher termites (Cubitermes spp.). Applied and Environmental Microbiology 65, 4490–4496.
Shi W, Moon CD, Leahy SC, Kang D, Froula J, Kittelmann S, Fan C, Deutsch S, Gagic D, Seedorf H, Kelly WJ, Atua R, Sang C, Soni P, Li D, Pinares-Patiño CS, McEwan JC, Janssen PH, Chen F, Visel A, Wang Z, Attwood GT, Rubin EM (2014) Methane yield phenotypes linked to differential gene expression in the sheep rumen microbiome. Genome Research 24, 1517–1525.
| Methane yield phenotypes linked to differential gene expression in the sheep rumen microbiome.Crossref | GoogleScholarGoogle Scholar | 24907284PubMed |
Smuts M, Meissner HH, Cronjé PB (1995) Retention time of digesta in the rumen: its repeatability and relationship with wool production of Merino rams1. Journal of Animal Science 73, 206–210.
| Retention time of digesta in the rumen: its repeatability and relationship with wool production of Merino rams1.Crossref | GoogleScholarGoogle Scholar | 7601735PubMed |
Subharat S, Shu D, Zheng T, Buddle BM, Janssen PH, Luo D, Wedlock DN (2015) Vaccination of cattle with a methanogen protein produces specific antibodies in the saliva which are stable in the rumen. Veterinary Immunology and Immunopathology 164, 201–207.
| Vaccination of cattle with a methanogen protein produces specific antibodies in the saliva which are stable in the rumen.Crossref | GoogleScholarGoogle Scholar | 25782351PubMed |
Subharat S, Shu D, Zheng T, Buddle BM, Kaneko K, Hook S, Janssen PH, Wedlock DN (2016) Vaccination of sheep with a methanogen protein provides insight into levels of antibody in saliva needed to target ruminal methanogens. PLoS One 11, e0159861
| Vaccination of sheep with a methanogen protein provides insight into levels of antibody in saliva needed to target ruminal methanogens.Crossref | GoogleScholarGoogle Scholar | 27472482PubMed |
Ulyatt MJ, McCrabb GJ, Baker SK, Lassey KR (1999) Accuracy of SF6 tracer technology and alternatives for field measurements. Australian Journal of Agricultural Research 50, 1329–1334.
| Accuracy of SF6 tracer technology and alternatives for field measurements.Crossref | GoogleScholarGoogle Scholar |
Wallace RJ, Rooke JA, McKain N, Duthie C-A, Hyslop JJ, Ross DW, Waterhouse A, Watson M, Roehe R (2015) The rumen microbial metagenome associated with high methane production in cattle. BMC Genomics 16, 839
| The rumen microbial metagenome associated with high methane production in cattle.Crossref | GoogleScholarGoogle Scholar | 26494241PubMed |
Wedlock DN, Janssen PH, Leahy SC, Shu D, Buddle BM (2013) Progress in the development of vaccines against rumen methanogens. animal 7, 244–252.
| Progress in the development of vaccines against rumen methanogens.Crossref | GoogleScholarGoogle Scholar | 23739467PubMed |
Weimer PJ (1998) Manipulating ruminal fermentation: a microbial ecological perspective. Journal of Animal Science 76, 3114–3122.
| Manipulating ruminal fermentation: a microbial ecological perspective.Crossref | GoogleScholarGoogle Scholar | 9928617PubMed |
Whitelaw F, Eadie JM, Bruce L, Shand W (1984) Methane formation in faunated and ciliate-free cattle and its relationship with rumen volatile fatty acid proportions. British Journal of Nutrition 52, 261–275.
| Methane formation in faunated and ciliate-free cattle and its relationship with rumen volatile fatty acid proportions.Crossref | GoogleScholarGoogle Scholar | 6433970PubMed |
Williams YJ, Rea SM, Popovski S, Pimm CL, Williams AJ, Toovey AF, Skillman LC, Wright A-DG (2008) Reponses of sheep to a vaccination of entodinial or mixed rumen protozoal antigens to reduce rumen protozoal numbers. British Journal of Nutrition 99, 100–109.
| Reponses of sheep to a vaccination of entodinial or mixed rumen protozoal antigens to reduce rumen protozoal numbers.Crossref | GoogleScholarGoogle Scholar | 17697432PubMed |
Williams YJ, Popovski S, Rea SM, Skillman LC, Toovey AF, Northwood KS, Wright A-DG (2009) A vaccine against rumen methanogens can alter the composition of archaeal populations. Applied and Environmental Microbiology 75, 1860–1866.
| A vaccine against rumen methanogens can alter the composition of archaeal populations.Crossref | GoogleScholarGoogle Scholar | 19201957PubMed |
Wright ADG, Kennedy P, O’Neill CJ, Toovey AF, Popovski S, Rea SM, Pimm CL, Klein L (2004) Reducing methane emissions in sheep by immunization against rumen methanogens. Vaccine 22, 3976–3985.
| Reducing methane emissions in sheep by immunization against rumen methanogens.Crossref | GoogleScholarGoogle Scholar |
Yan T, Agnew RE, Gordon FJ, Porter MG (2000) Prediction of methane energy output in dairy and beef cattle offered grass silage-based diets. Livestock Production Science 64, 253–263.
| Prediction of methane energy output in dairy and beef cattle offered grass silage-based diets.Crossref | GoogleScholarGoogle Scholar |
Yáñez-Ruiz DR, Abecia L, Newbold CJ (2015) Manipulating rumen microbiome and fermentation through interventions during early life: a review. Frontiers in Microbiology 6, 1133
| Manipulating rumen microbiome and fermentation through interventions during early life: a review.Crossref | GoogleScholarGoogle Scholar | 26528276PubMed |
Yang MG, Manoharan K, Mickelsen O (1970) Nutritional contribution of volatile fatty acids from the cecum of rats. Journal of Nutrition 100, 545–550.
| Nutritional contribution of volatile fatty acids from the cecum of rats.Crossref | GoogleScholarGoogle Scholar | 5443827PubMed |
Zhang L, Huang X, Xue B, Peng Q, Wang Z, Yan T, Wang L (2015) Immunization against rumen methanogenesis by vaccination with a new recombinant protein. PLoS One 10, e0140086
| Immunization against rumen methanogenesis by vaccination with a new recombinant protein.Crossref | GoogleScholarGoogle Scholar | 26713757PubMed |