Sustainable Milk and Meat Production while Reducing Methane Emissions from Livestock Enteric Fermentation

Ruminants produce all the milk and most of the meat demanded by humans; however, ruminant production generates large quantities of greenhouse gases (GHG), around 15% of anthropogenic emissions of GHG are attributed to ruminant production. Therefore there is an urgent need to develop sustainable alternatives to mitigate GHG emissions by ruminants and to increase the supply of high quality protein for human consumption in a climate change scenario. The objective of this work is to present sustainable options to mitigate methane (CH4) production from enteric fermentation by cattle and to illustrate how productivity can be increased at the same time. We conducted several experiments to measure CH4 emission in vivo by cattle in order to estimate emission factors in the temperate and tropical climate regions of Mexico followed by inventory calculation. We then evaluated the supplementation to cattle of different tanniferous plants to reduce enteric CH4 formation and finally established two mitigation scenarios for each region. Leucaena leucocephala and Cosmos bipinnatus are the tanniferous plants that produced the largest reduction in CH4 formation. In scenario 1, a moderate mitigation scenario, it was assumed 16% reduction of enteric CH4 emission in the temperate climate regions (TEMP) and 36% in the tropical regions (TROP) with cattle population of 37.8 million heads, from which 22.3 are in the TEMP (emission factor 529 l/day/head) and 15.5 in the TROP (emission factor 137 l/day/head). Reduction potential resulting from the use of C. bipinnatus and L. Leucocephala over a year is 1,203Gg. In scenario 2, a high mitigation situation, it was assumed a 26% reduction of CH4 emission in the TEMP and 36% in the TROP and the same cattle population. The reduction potential resulting from C. bipinnatus and L. Leucocephala use in a year is 1,512 Gg. Results showed that in both scenarios the CH4 released by enteric fermentation could be reduced by the use of the plants evaluated. Increased productivity results from higher stocking rates achieved with the use of Leucaena in tropical regions, better animal performance due to enhanced animal nutrition and lower use of concentrate feeds. Our approach is novel in Latin America because it used in vivo estimated emission factors and provided a sustainable way to reduce inventories of this gas.