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Effect of ammonia concentration on rumen microbial protein production in vitro

Published online by Cambridge University Press:  15 November 2021

Richard J. Dewhurst*
Affiliation:
Dairy Research & Innovation Centre, SRUC, Barony Campus, Parkgate, Dumfries, DG1 3NE, UK
John R. Newbold
Affiliation:
Dairy Research & Innovation Centre, SRUC, Barony Campus, Parkgate, Dumfries, DG1 3NE, UK
*
*Corresponding author: Dr R. J. Dewhurst, email [email protected]
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Abstract

We review key findings of one the most cited papers in the 75-year history of BJN. We then identify important consequent developments, as well as opportunities to use analytical and molecular biology advances to maximise conversion of non-protein nitrogen into microbial protein.

Type
Full Papers
Copyright
© The Author(s), 2021. Published by Cambridge University Press on behalf of The Nutrition Society

Ruminants are exquisitely adapted to convert low-grade human inedible feedstuffs into high-quality protein foods. Most notably, they convert non-protein nitrogen into high-quality protein in milk, beef and lamb as demonstrated in the classical study of Virtanen(Reference Virtanen1) in which dairy cows produced milk from a diet where the only N sources were urea and ammonium salts. Central to this ability is the synthesis of microbial protein in the rumen, much of which utilises ammonia.

‘Metabolisable protein’ systems for ruminants developed over the last 4 decades have attempted to incorporate estimates of protein degradation and microbial protein synthesis (MPS) in the rumen into feeding standards and rationing systems. However, both degradation and synthesis measurements are difficult to accomplish in vivo, requiring fistulated cows, and subject to large experimental errors. Before Satter and Slyter’s paper, it was recognised that non-protein nitrogen is often not well utilised in diets containing high levels of non-protein nitrogen or low fermentable energy, but it was not clear at what ammonia level MPS is limited.

Satter and Slyter(Reference Satter and Slyter2) adopted an in vitro approach, where it is easier to control and measure inputs and outputs to understand the effects of N supply on MPS. Just as in Virtanen’s work, the use of protein-free diets allowed the authors to measure MPS directly – in this case as true (tungstic acid precipitable) protein.

Key findings

Satter and Slyter’s in vitro approach allowed them to conduct a series of experiments evaluating a wide range of basal diets, both synthetic (without true protein) and natural (with true protein) with graded additions of urea to evaluate the effects of rumen N supply. The paper is most cited as the basis for asserting 50 mg/l ammonia-N as the minimum level to avoid constraining MPS. Ammonia concentrations in effluent from their in vitro vessels increased above levels equivalent to 120–140 g crude protein per kg DM in the diet, whilst tungstic acid precipitable N plateaued at this level. Below this level, there was a major and linear decline in MPS, with more modest reductions in the production of volatile fatty acids and methane. Very high levels of ammonia-N (800 mg/l) did not impair MPS. Whilst in vitro systems are easier to control and measure, the authors recognised limitations due to the absence of absorption and N recycling seen in vivo.

Developments since publication

The paper accelerated to be cited over 30 times in 2000 and has been consistently cited 30–50 times in each subsequent year. The citing papers often refer to the 50 mg/l ammonia-N minima and have spanned across a range of diet types, additives and feeding strategies in many countries.

The paper was quickly challenged by in vivo work from Reference Cabrita, Dewhurst and AbreuMehrez et al.(Reference Mehrez, Ørskov and McDonald3) suggesting that a much higher rumen ammonia-N concentration (194 mg/l) was needed to optimise in situ DM disappearance of barley. Those sheep were only fed mineralised rolled barley, so it seems likely that urea addition (and the resultant increased rumen ammonia) may have exerted other effects, including through rumen pH. Our own in vitro work on rumen acidogenicity of diverse feeds(Reference Wadhwa, Beck and Borgida4) illustrates the effects of degraded N on rumen pH. Odle and Schafer(Reference Odle and Schaefer5) conducted a similar study with beef cattle and showed optimal ammonia-N of 125 mg/l for degradation of barley and 61 mg/l for degradation of maize. Indeed, earlier in vivo work mentioned by Satter and Slyter(Reference Hume, Moir and Somers6) also suggested a higher requirement, around 130 mg/l, to maximise MPS. When supplementing urea to low protein fibre sources, Soliva et al.(Reference Soliva, Amelchanka and Kreuzer7) showed that the level at which ammonia-N restricted in vitro fermentability of fibre varied between fibre sources (from 31 mg/l for apple pomace to 92 mg/l for Brachiaria hay). It may be that the optimum level of ammonia-N for MPS differs from that for optimal fibre digestion.

Whilst 50 mg/l ammonia-N is often cited as a minimum, some more recent in vitro work(Reference Sari, Ferret and Calsamiglia8) and other work from that group cited therein suggested that even lower rumen ammonia-N concentrations did not limit MPS. Over the intervening years, it has become clear that ammonia-N concentration does not tell the whole story about the effects of degradable protein on microbial growth. Rapid growth of rumen bacteria is supported by amino acids and peptides(Reference Cotta and Russell9Reference Calsamiglia, Ferret and Reynolds11).

Requirements for rumen N are usually expressed relative to rumen fermentable energy supply on a daily basis, and there was some interest in the effects of diurnal variation in the synchrony of energy and N supply on MPS, but no consistent effects from in vivo studies (reviewed by Cabrita et al. (Reference Cabrita, Dewhurst and Abreu12)). It is likely that the ruminant possesses mechanisms (notably the ability to recycle surplus N in saliva and the ability of rumen micro-organisms to accumulate storage polysaccharides during short periods of N deficiency) to ‘buffer’ short-term (within day) fluctuations in the ratio of degradable N: fermentable carbohydrate.

Future directions

Optimising protein feeding for ruminants is highly topical again as we need to maximise the beneficial effects of converting non-protein nitrogen into MPS without excess rumen N leading to increased urinary N and consequent issues with nitrous oxide and ammonia losses to the air and nitrate losses to water. The fundamental observation that MPS is maximised at relatively low dietary protein levels remains useful in this quest, as are the many observations of other factors increasing MPS without increasing dietary crude protein. Prediction of MPS remains problematic, with most recent modelling accounting for only 40 % of variation(Reference Galyean and Tedeschi13). One approach to circumvent these challenges has been the use of proxies for MPS, including urinary purine derivatives and milk odd and branched chain fatty acids(Reference Dewhurst, Davies and Merry14), but analytical challenges mean that these have been restricted to research settings. Whilst Satter and Slyter(Reference Satter and Slyter2) noted relatively normal populations of cellulolytic bacteria and entodiniomorph protozoa in their system, sequencing techniques would now allow much better analysis of the microbial community, whether in vitro or in vivo. Rumen metagenomics techniques, both at the taxa and gene levels, have been used to predict other rumen-related traits, including rumen methanogenesis and feed conversion efficiency(Reference Lima, Auffret and Stewart15,Reference Martinez-Alvarez, Auffret and Stewart16) . We expect that this approach will support the next advances in predicting and enhancing MPS, whether by dietary or host genetic means. Lu et al.(Reference Lu, Xu and Shen17) explored the relative abundance of microbial genes involved in energy generation in relation to MPS and showed many effects of dietary energy level, but not dietary protein level; the same was true when considering microbial taxa.

The model whereby soluble proteins are deemed to be rapidly degraded in the rumen and the resultant ammonia inefficiently incorporated into microbial protein has been challenged with a suggestion that some soluble proteins may be degraded more slowly, pass from the rumen as ‘undegradable soluble protein’, be directly adsorbed onto bacterial cells or taken up into intracellular pools(Reference Hedqvist and Udén18,Reference Stefański, Ahvenjärvi and Vanhatalo19) . Whilst the next advances in enhancing rumen N metabolism may still use the in vitro approach of Satter and Slyter, they will be able to draw on advances in describing N fractions in feed and digesta, as well as microbial taxa and genes.

Acknowledgements

SRUC received funding from the Scottish Government’s Strategic Research Programme.

RJD and JRN both contributed to the writing and editing of the manuscript and approved the final version.

There are no conflicts of interest.

Footnotes

This paper was commissioned as part of the BJN’s 75th Anniversary celebrations, reviewing the impact of some of the most cited papers published in the journal over that period.

References

Virtanen, AI (1966) Milk production of cows on protein-free feed. Science 153, 16031614.CrossRefGoogle ScholarPubMed
Satter, LD & Slyter, LL (1974) Effect of ammonia concentration on rumen microbial protein production in vitro. Br J Nutr 32, 199208.CrossRefGoogle ScholarPubMed
Mehrez, AZ, Ørskov, ER & McDonald, I (1977) Rates of rumen fermentation in relation to ammonia concentration. Br J Nutr 38, 437443.CrossRefGoogle ScholarPubMed
Wadhwa, D, Beck, NFG, Borgida, LP, et al. (2001) Development of a simple in vitro assay for estimating net rumen acid load from diet ingredients. J Dairy Sci 84, 11091117.CrossRefGoogle ScholarPubMed
Odle, J & Schaefer, DM (1987) Influence of rumen ammonia concentration on the rumen degradation rates of barley and maize. Br J Nutr 51, 127138.CrossRefGoogle Scholar
Hume, ID, Moir, RJ & Somers, M (1970) Synthesis of microbial protein in the rumen. 1. Influence of the level of nitrogen intake. Austr J Agric Res 21, 283296.CrossRefGoogle Scholar
Soliva, CR, Amelchanka, SL & Kreuzer, M (2015) The requirements for rumen-degradable protein per unit of fermentable organic matter differ between fibrous feed sources. Front Microbiol 6, 715.CrossRefGoogle ScholarPubMed
Sari, M, Ferret, A & Calsamiglia, S (2015) Effect of pH on in vitro microbial fermentation and nutrient flow in diets containing barley straw or non-forage fiber sources. Anim Feed Sci Technol 200, 1724.CrossRefGoogle Scholar
Cotta, MA & Russell, JB (1982) Effect of peptides and amino acids on efficiency of rumen bacterial protein synthesis in continuous culture. J Dairy Sci 65, 226234.CrossRefGoogle Scholar
Carro, MD & Miller, EL (1999) Effect of supplementing a fibre basal diet with different nitrogen forms on ruminal fermentation and microbial growth in an in vitro semi-continuous culture system (RUSITEC). Br J Nutr 82, 149157.CrossRefGoogle Scholar
Calsamiglia, S, Ferret, A, Reynolds, CK, et al. (2010) Strategies for optimizing nitrogen use by ruminants. Animal 4, 11841196.CrossRefGoogle ScholarPubMed
Cabrita, ARJ, Dewhurst, RJ, Abreu, JMF, et al. (2006) Critical evaluation of the effects of synchronising the availability of N and energy in the rumen. Anim Res 55, 124.CrossRefGoogle Scholar
Galyean, M & Tedeschi, LO (2014) Predicting microbial protein synthesis in beef cattle: relationship to intakes of total digestible nutrients and crude protein. J Anim Sci 92, 50995111.CrossRefGoogle ScholarPubMed
Dewhurst, RJ, Davies, DR & Merry, RJ (2000) Microbial protein supply from the rumen. Anim Feed Sci Technol 85, 121.CrossRefGoogle Scholar
Lima, J, Auffret, MD, Stewart, RD, et al. (2019) Identification of rumen microbial genes involved in pathways linked to appetite, growth, and feed conversion efficiency in cattle. Front Genet 10, 701.CrossRefGoogle ScholarPubMed
Martinez-Alvarez, M, Auffret, MD, Stewart, RD, et al. (2020) Identification of complex rumen microbiome interaction within diverse functional niches as mechanisms affecting the variation of methane emissions in bovine. Front Microbiol 11, 659.CrossRefGoogle Scholar
Lu, Z, Xu, Z, Shen, Z, et al. (2019) Dietary energy level promotes rumen microbial protein synthesis by improving the energy productivity of the ruminal microbiome. Front Microbiol 10, 847.CrossRefGoogle ScholarPubMed
Hedqvist, H & Udén, P (2006) Measurement of soluble protein degradation in the rumen. Anim Feed Sci Technol 126, 121.CrossRefGoogle Scholar
Stefański, T, Ahvenjärvi, S, Vanhatalo, A, et al. (2020) Ruminal metabolism of ammonia N and rapeseed meal soluble N fraction. J Dairy Sci 103, 70817093.CrossRefGoogle ScholarPubMed