Methane mitigation in ruminants: from microbe to the farm scale

The study determined the performance of equations to predict enteric methane (CH 4 ) from beef cattle fed forage-and grain-based diets. Many equations are available to predict CH 4 from beef cattle and the predictions vary substantially among equations. The aims were to (1) construct a database of CH 4 emissions for beef cattle from published literature, and (2) identify the most precise and accurate extant CH 4 prediction models for beef cattle fed diets varying in forage content. The database was comprised of treatment means of CH 4 production from in vivo beef studies published from 2000 to 2015. Criteria to include data in the database were as follows: animal description, intakes, diet composition and CH 4 production. In all, 54 published equations that predict CH 4 production from diet composition were evaluated. Precision and accuracy of the equations were evaluated using the concordance correlation coefficient (r c ), root mean square prediction error (RMSPE), model efficiency and analysis of errors. Equations were ranked using a combined index of the various statistical assessments based on principal component analysis. The final database contained 53 studies and 207 treatment means that were divided into two data sets: diets containing ⩾400 g/kg dry matter (DM) forage (n = 116) and diets containing ⩽200 g/kg DM forage (n = 42). Diets containing between ⩽400 and ⩾200 g/kg DM forage were not included in the analysis because of their limited numbers (n = 6). Outliers, treatment means where feed was fed restrictively and diets with CH 4 mitigation additives were omitted (n = 43). Using the high-forage dataset the best-fit equations were the International Panel on Climate Change Tier 2 method, 3 equations for steers that considered gross energy intake (GEI) and body weight and an equation that considered dry matter intake and starch:neutral detergent fiber with r c ranging from 0.60 to 0.73 and RMSPE from 35.6 to 45.9 g/day. For the high-grain diets, the 5 best-fit equations considered intakes of metabolisable energy, cellulose, hemicellulose and fat, or for steers GEI and body weight, with r c ranging from 0.35 to 0.52 and RMSPE from 47.4 to 62.9 g/day. Ranking of extant CH 4 prediction equations for their accuracy and precision differed with forage content of the diet. When used for cattle fed high-grain diets, extant CH 4 prediction models were generally imprecise and lacked accuracy.

Section: Discussionmentioning

confidence: 99%

An evaluation of the accuracy and precision of methane prediction equations for beef cattle fed high-forage and high-grain diets

Escobar-Bahamondes

Oba

Beauchemin

2017

“…A range of different strategies are being investigated to reduce methane emissions from farmed ruminants (reviewed by Martin et al, 2010;Buddle et al, 2011;Clark, 2013). Vaccination of ruminants against rumen methanogens has the potential to reduce methane emissions by decreasing the number or activity of methanogens in the rumen.…”

Section: Introductionmentioning

confidence: 99%

Progress in the development of vaccines against rumen methanogens

Wedlock

Janssen

Leahy

et al. 2013

Vaccination against rumen methanogens offers a practical approach to reduce methane emissions in livestock, particularly ruminants grazing on pasture. Although successful vaccination strategies have been reported for reducing the activity of the rumen-dwelling organism Streptococcus bovis in sheep and S. bovis and Lactobacillus spp. in cattle, earlier approaches using vaccines based on whole methanogen cells to reduce methane production in sheep have produced less promising results. An anti-methanogen vaccine will need to have broad specificity against methanogens commonly found in the rumen and induce antibody in saliva resulting in delivery of sufficiently high levels of antibodies to the rumen to reduce methanogen activity. Our approach has focussed on identifying surface and membrane-associated proteins that are conserved across a range of rumen methanogens. The identification of potential vaccine antigens has been assisted by recent advances in the knowledge of rumen methanogen genomes. Methanogen surface proteins have been shown to be immunogenic in ruminants and vaccination of sheep with these proteins induced specific antibody responses in saliva and rumen contents. Current studies are directed towards identifying key candidate antigens and investigating the level and types of salivary antibodies produced in sheep and cattle vaccinated with methanogen proteins, stability of antibodies in the rumen and their impact on rumen microbial populations. In addition, there is a need to identify adjuvants that stimulate high levels of salivary antibody and are suitable for formulating with protein antigens to produce a low-cost and effective vaccine.Keywords: vaccine, antigen, antibody, methane, methanogens, Methanobrevibacter ruminantium Implications A number of different mitigation strategies are being investigated for reducing methane emissions from livestock, including the development of vaccines that specifically target the methane-producing methanogens in the rumen. Previous studies on vaccinating ruminants against the rumen-dwelling organisms Streptococcus bovis and Lactobacillus spp. have demonstrated the feasibility of vaccinating animals to produce salivary antibodies that neutralise the activity of these microbes in the rumen (Shu et al., 1999(Shu et al., , 2000a(Shu et al., , 2000b(Shu et al., and 2001Gill et al., 2000). Owing to the complexity of the rumen microbiota and diversity of methanogens in the rumen, an effective vaccine for reducing methane emissions from ruminants will need to target a wide range of methanogens in the rumen among an even more diverse assemblage of bacteria, fungi and protozoa. This paper reviews the progress towards developing an anti-methanogen vaccine. IntroductionA range of different strategies are being investigated to reduce methane emissions from farmed ruminants (reviewed by Martin et al., 2010;Buddle et al., 2011;Clark, 2013). Vaccination of ruminants against rumen methanogens has the potential to reduce methane emissions by decreasing the number or activity of meth...

“…Increasing the concentration of dietary lipid has been shown to reduce CH 4 emissions from ruminants (Martin et al, 2010;Grainger and Beauchemin, 2011;Patra, 2013). This is achieved through various mechanisms: fatty acids are not fermented in the rumen and therefore increasing dietary lipid concentration reduces the proportion of feed which is fermentable within the rumen; lipids can also reduce CH 4 production by coating fibre particles, reducing their digestibility, and by reducing the numbers and activity of the rumen methanogens and protozoa responsible for methanogenesis (Johnson and Johnson, 1995;Patra, 2013).…”

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confidence: 99%

“…Although increased concentrations of dietary lipid has been shown to reduce CH 4 from ruminants (Martin et al, 2010;Grainger and Beauchemin, 2011;Patra, 2013), at high concentrations in the diet lipid can negatively affect DMI and productivity (Brask et al, 2013). Based on a meta-analysis, Patra (2013) demonstrated that dietary lipid concentrations in excess of 6% cause problems with productivity.…”

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confidence: 99%

Impact of adding nitrate or increasing the lipid content of two contrasting diets on blood methaemoglobin and performance of two breeds of finishing beef steers

Duthie

Rooke

Troy

et al. 2016

Adding nitrate to the diet or increasing the concentration of dietary lipid are effective strategies for reducing enteric methane emissions. This study investigated their effect on health and performance of finishing beef cattle. The experiment was a two × two × three factorial design comprising two breeds (CHX, crossbred Charolais; LU, Luing); two basal diets consisting of (g/kg dry matter (DM), forage to concentrate ratios) 520 : 480 (Mixed) or 84 : 916 (Concentrate); and three treatments: (i) control with rapeseed meal as the main protein source replaced with either (ii) calcium nitrate (18 g nitrate/kg diet DM) or (iii) rapeseed cake (RSC, increasing acid hydrolysed ether extract from 25 to 48 g/kg diet DM). Steers (n = 84) were allocated to each of the six basal diet × treatments in equal numbers of each breed with feed offered ad libitum. Blood methaemoglobin (MetHb) concentrations (marker for nitrate poisoning) were monitored throughout the study in steers receiving nitrate. After dietary adaptation over 28 days, individual animal intake, performance and feed efficiency were recorded for a test period of 56 days. Blood MetHb concentrations were low and similar up to 14 g nitrate/kg diet DM but increased when nitrate increased to 18 g nitrate/kg diet DM ( P < 0.001). An interaction between basal diet and day ( P < 0.001) indicated that MetHb% was consistently greater in Concentrate -than Mixed-fed steers at 18 g nitrate/kg diet DM. Maximum individual MetHb% was 15.4% (of total Hb), which is lower than considered clinically significant (30%). MetHb concentrations for individual steers remained consistent across time. Concentrate-fed steers were more efficient (lower residual feed intake (RFI) values) than Mixed-fed steers ( P < 0.01), with lower dry matter intake (DMI) (kg/day) ( P < 0.001) and similar average daily gain (ADG). CHX steers were more efficient (lower RFI; P < 0.01) than LU steers with greater ADG ( P < 0.01), lower DMI (/kg BW; P < 0.01) and lower fat depth ( P < 0.001). ADG, BW or DMI did not differ across dietary treatments ( P > 0.05). Neither basal diet nor treatment affected carcass quality ( P > 0.05), but CHX steers achieved a greater killing out proportion ( P < 0.001) than LU steers. Thus, adding nitrate to the diet or increasing the level of dietary lipid through the use of cold-pressed RSC, did not adversely affect health or performance of finishing beef steers when used within the diets studied.