Responses in digestion, rumen fermentation and microbial populations to inhibition of methane formation by a halogenated methane analogue

Mitsumori, Makoto; Shinkai, Takumi; Takénaka, Akio; Enishi, Osamu; Higuchi, Koji; Kobayashi, Yasuhiko; Nonaka, Itoko; Asanuma, Narito; Denman, Stuart E.; McSweeney, Christopher S.

doi:10.1017/s0007114511005794

Cited by 110 publications

(169 citation statements)

References 39 publications

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“…Addition of BCM to rumen contents in vitro, or to the rumen directly, strongly inhibited CH 4 production (McCrabb et al 1997;Goel et al 2009;Mitsumori et al 2012). The most successful compounds tested in vivo have been the chlorinated hydrocarbons, including BCM, 2-bromoethane sulfonate (BES), chloroform and cyclodextrin.…”

Section: Mitigation Of Enteric Ch 4 Per Animal or Per Unit Of Digestimentioning

confidence: 99%

“…McCrabb et al 1997). Surprisingly, with this type of inhibition, there is no reduction in feed digestibility or production and the reduction in CH 4 release is accompanied by a concomitant stoichiometric production of H 2 (Mitsumori et al 2012). If it is assumed that the H 2 is produced in fermentative sites in the biofilm, it is reasonable to expect an increased partial pressure of H 2 at these sites and, therefore, adverse effects on feed digestion and intake.…”

Section: Introductionmentioning

confidence: 99%

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Interactions between microbial consortia in biofilms: a paradigm shift in rumen microbial ecology and enteric methane mitigation

Leng¹

2014

Anim. Prod. Sci.

127

104

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Abstract. Minimising enteric CH 4 emissions from ruminants is a current research priority because CH 4 contributes to global warming. The most effective mitigation strategy is to adjust the animal's diet to complement locally available feed resources so that optimal production is gained from a minimum of animals. This essay concentrates on a second strategy -the use of feed additives that are toxic to methanogens or that redirect H 2 (and electrons) to inhibit enteric CH 4 emissions from individual animals. Much of the published research in this area is contradictory and may be explained when the microbial ecology of the rumen is considered.Rumen microbes mostly exist in organised consortia within biofilms composed of self-secreted extracellular polymeric substances attached to or within feed particles. In these biofilms, individual colonies are positioned to optimise their use of preferred intermediates from an overall process of organic matter fermentation that generates end-products the animal can utilise. Synthesis of CH 4 within biofilms prevents a rise in the partial pressure of H 2 (pH 2 ) to levels that inhibit bacterial dehydrogenases, and so reduce fermentation rate, feed intake and digestibility. In this context, hypotheses are advanced to explain changes in hydrogen disposal from the biofilms in the rumen resulting from use of anti-methanogenic feed additives as follows.Nitrate acts as an alternative electron sink when it is reduced via NO 2 -to NH 3 and CH 4 synthesis is reduced. However, efficiency of CH 4 mitigation is always lower than that predicted and decreases as NO 3 -ingestion increases. Suggested reasons include (1) variable levels of absorption of NO 3 -or NO 2 -from the rumen and (2) increases in H 2 production. One suggestion is that NO 3 -reduction may lower pH 2 at the surface of biofilms, thereby creating an ecological niche for growth of syntrophic bacteria that oxidise propionate and/or butyrate to acetate with release of H 2 .Chlorinated hydrocarbons also inhibit CH 4 synthesis and increase H 2 and formate production by some rumen methanogens. Formate diffuses from the biofilm and is converted to HCO 3 -and H 2 in rumen fluid and is then excreted via the breath. Short-chain nitro-compounds inhibit both CH 4 and formate synthesis when added to ruminal fluid but have little or no effect in redirecting H 2 to other sinks, so the pH 2 within biofilms may increase to levels that support reductive acetogenesis. Biochar or activated charcoal may also alter biofilm activity and reduce net CH 4 synthesis; direct electron transfer between microbes within biofilms may also be involved. A final suggestion is that, during their sessile life stage, protozoa interact with biofilm communities and help maintain pH 2 in the biofilm, supporting methanogenesis.

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Section: Mitigation Of Enteric Ch 4 Per Animal or Per Unit Of Digestimentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Interactions between microbial consortia in biofilms: a paradigm shift in rumen microbial ecology and enteric methane mitigation

Leng¹

2014

Anim. Prod. Sci.

127

104

View full text Add to dashboard Cite

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“…Although some of these strategies have shown promise, not all directly target methanogens. Halogenated compounds (e.g., chloroform and bromochloromethane) are highly potent inhibitors of methanogenesis in ruminants (6,(16)(17)(18)(19)(20)(21). However, these compounds are not considered appropriate for use in current animal husbandry due to environmental, human health, and animal welfare concerns.…”

mentioning

confidence: 99%

Development of Multiwell-Plate Methods Using Pure Cultures of Methanogens To Identify New Inhibitors for Suppressing Ruminant Methane Emissions

Weimar

Cheung

Dey

et al. 2017

Appl Environ Microbiol

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Hydrogenotrophic methanogens typically require strictly anaerobic culturing conditions in glass tubes with overpressures of H 2 and CO 2 that are both time-consuming and costly. To increase the throughput for screening chemical compound libraries, 96-well microtiter plate methods for the growth of a marine (environmental) methanogen Methanococcus maripaludis strain S2 and the rumen methanogen Methanobrevibacter species AbM4 were developed. A number of key parameters (inoculum size, reducing agents for medium preparation, assay duration, inhibitor solvents, and culture volume) were optimized to achieve robust and reproducible growth in a high-throughput microtiter plate format. The method was validated using published methanogen inhibitors and statistically assessed for sensitivity and reproducibility. The Sigma-Aldrich LOPAC library containing 1,280 pharmacologically active compounds and an in-house natural product library (120 compounds) were screened against M. maripaludis as a proof of utility. This screen identified a number of bioactive compounds, and MIC values were confirmed for some of them against M. maripaludis and M. AbM4. The developed method provides a significant increase in throughput for screening compound libraries and can now be used to screen larger compound libraries to discover novel methanogen-specific inhibitors for the mitigation of ruminant methane emissions.IMPORTANCE Methane emissions from ruminants are a significant contributor to global greenhouse gas emissions, and new technologies are required to control emissions in the agriculture technology (agritech) sector. The discovery of small-molecule inhibitors of methanogens using high-throughput phenotypic (growth) screening against compound libraries (synthetic and natural products) is an attractive avenue. However, phenotypic inhibitor screening is currently hindered by our inability to grow methanogens in a high-throughput format. We have developed, optimized, and validated a highthroughput 96-well microtiter plate assay for growing environmental and rumen methanogens. Using this platform, we identified several new inhibitors of methanogen growth, demonstrating the utility of this approach to fast track the development of methanogen-specific inhibitors for controlling ruminant methane emissions.KEYWORDS methanogen, greenhouse gas, Methanococcus maripaludis, highthroughput, rumen, Methanobrevibacter M ethane emissions from ruminants are a significant contributor to global greenhouse gas emissions (1). In countries such as New Zealand, with a large pasturebased livestock sector, greenhouse gas emissions from agriculture represent approxi-

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“…BCM supplementation at 0.3 g/100 kg of body weight (BW) significantly decreased methane production and methanogen abundance in Japanese goats (5), lactating dairy goats (6), steers (7), and Sprague-Dawley (SD) rats (8). BCM inhibits methanogenesis by reacting with cobalamin (9).…”

mentioning

confidence: 99%

Bromochloromethane, a Methane Analogue, Affects the Microbiota and Metabolic Profiles of the Rat Gastrointestinal Tract

Luo

Zhu

2016

Appl Environ Microbiol

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Bromochloromethane (BCM), an inhibitor of methanogenesis, has been used in animal production. However, little is known about its impact on the intestinal microbiota and metabolic patterns. The present study aimed to investigate the effect of BCM on the colonic bacterial community and metabolism by establishing a Wistar rat model. Twenty male Wistar rats were randomly divided into two groups (control and treated with BCM) and raised for 6 weeks. Bacterial fermentation products in the cecum were determined, and colonic methanogens and sulfate-reducing bacteria (SRB) were quantified. The colonic microbiota was analyzed by pyrosequencing of the 16S rRNA genes, and metabolites were profiled by gas chromatography and mass spectrometry. The results showed that BCM did not affect body weight and feed intake, but it did significantly change the intestinal metabolic profiles. Cecal protein fermentation was enhanced by BCM, as methylamine, putrescine, phenylethylamine, tyramine, and skatole were significantly increased. Colonic fatty acid and carbohydrate concentrations were significantly decreased, indicating the perturbation of lipid and carbohydrate metabolism by BCM. BCM treatment decreased the abundance of methanogen populations, while SRB were increased in the colon. BCM did not affect the total colonic bacterial counts but significantly altered the bacterial community composition by decreasing the abundance of actinobacteria, acidobacteria, and proteobacteria. The results demonstrated that BCM treatment significantly altered the microbiotic and metabolite profiles in the intestines, which may provide further information on the use of BCM in animal production. Bromochloromethane (BCM) (CH 2 BrCl, CAS no. 74-97-5) is an analog of dihalogenated methane. Unintentional consumption of this unregulated halomethane as a by-product of disinfection in drinking water is one of the major sources for BCM exposure (1, 2) and has been linked to an increased risk of stomach cancer in Finland (3). Long-term exposure to BCM may cause hepato-and nephrotoxicity in humans. Budnik et al. (4) reviewed 542 publications between 1990 and 2011 and found 91 publications referring to the toxicity of halomethanes on lungs, skin, liver, muscle, spleen, kidneys, and the central nervous system. Although the gastrointestinal tract (GIT) comes in direct contact with ingested BCM, very few studies have focused on the influence of BCM on the GIT, let alone on the intestinal microbiota.BCM can be used as an antimethanogenic compound to decrease methane production. BCM supplementation at 0.3 g/100 kg of body weight (BW) significantly decreased methane production and methanogen abundance in Japanese goats (5), lactating dairy goats (6), steers (7), and Sprague-Dawley (SD) rats (8). BCM inhibits methanogenesis by reacting with cobalamin (9). Cobalamin-dependent enzymes, including cobalamin-dependent methionine synthase (10), methylmalonyl-coenzyme A (CoA) mutase, and glutamate mutase, contribute to the bacterial metabolism under physiological conditions. ...

show abstract

Responses in digestion, rumen fermentation and microbial populations to inhibition of methane formation by a halogenated methane analogue

Cited by 110 publications

References 39 publications

Interactions between microbial consortia in biofilms: a paradigm shift in rumen microbial ecology and enteric methane mitigation

Interactions between microbial consortia in biofilms: a paradigm shift in rumen microbial ecology and enteric methane mitigation

Development of Multiwell-Plate Methods Using Pure Cultures of Methanogens To Identify New Inhibitors for Suppressing Ruminant Methane Emissions

Bromochloromethane, a Methane Analogue, Affects the Microbiota and Metabolic Profiles of the Rat Gastrointestinal Tract

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