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Food, fibre and pharmaceuticals from animals
REVIEW

Managing the rumen to limit the incidence and severity of nitrite poisoning in nitrate-supplemented ruminants

J. V. Nolan A B , I. R. Godwin A , V. de Raphélis-Soissan A and R. S. Hegarty A
+ Author Affiliations
- Author Affiliations

A School of Environmental and Rural Science, University of New England, Armidale, NSW 2351, Australia.

B Corresponding author. Email: jnolan@une.edu.au

Animal Production Science 56(8) 1317-1329 https://doi.org/10.1071/AN15324
Submitted: 24 June 2015  Accepted: 13 November 2015   Published: 27 May 2016

Abstract

Inclusion of nitrate (NO3) in ruminant diets is a means of increasing non-protein nitrogen intake while at the same time reducing emissions of enteric methane (CH4) and, in Australia, gaining carbon credits. Rumen microorganisms contain intracellular enzymes that use hydrogen (H2) released during fermentation to reduce NO3 to nitrite (NO2), and then reduce the resulting NO2 to ammonia or gaseous intermediates such as nitrous oxide (N2O) and nitric oxide (NO). This diversion of H2 reduces CH4 formation in the rumen. If NO2 accumulates in the rumen, it may inhibit growth of methanogens and other microorganisms and this may further reduce CH4 production, but also lower feed digestibility. If NO2 is absorbed and enters red blood cells, methaemoglobin is formed and this lowers the oxygen-carrying capacity of the blood. Nitric oxide produced from absorbed NO2 reduces blood pressure, which, together with the effects of methaemoglobin, can, at times, lead to extreme hypoxia and death. Nitric oxide, which can be formed in the gut as well as in tissues, has a variety of physiological effects, e.g. it reduces primary rumen contractions and slows passage of digesta, potentially limiting feed intake. It is important to find management strategies that minimise the accumulation of NO2; these include slowing the rate of presentation of NO3 to rumen microbes or increasing the rate of removal of NO2, or both. The rate of reduction of NO3 to NO2 depends on the level of NO3 in feed and its ingestion rate, which is related to the animal’s feeding behaviour. After NO3 is ingested, its peak concentration in the rumen depends on its rate of solubilisation. Once in solution, NO3 is imported by bacteria and protozoa and quickly reduced to NO2. One management option is to encapsulate the NO3 supplement to lower its solubility. Acclimating animals to NO3 is an established management strategy that appears to limit NO2 accumulation in the rumen by increasing microbial nitrite reductase activity more than nitrate reductase activity; however, it does not guarantee complete protection from NO2 poisoning. Adding concentrates into nitrate-containing diets also helps reduce the risk of poisoning and inclusion of microbial cultures with enhanced NO2-reducing properties is another potential management option. A further possibility is to inhibit NO2 absorption. Animals differ in their tolerance to NO3 supplementation, so there may be opportunities for breeding animals more tolerant of dietary NO3. Our review aims to integrate current knowledge of microbial processes responsible for accumulation of NO2 in rumen fluid and to identify management options that could minimise the risks of NO2 poisoning while reducing methane emissions and maintaining or enhancing livestock production.

Additional keywords: behaviour, greenhouse gas, methane, microbial processes, supplementation.


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