- 1International Center for Tropical Agriculture (CIAT), Cali, Colombia
- 2CGIAR Research Program on Climate Change Agriculture and Food Security (CCAFS), Palmira, Colombia
- 3Embrapa Pecuária Sudeste, São Carlos, Brazil
- 4Ministerio de Agricultura y Ganadería, San Jose, Costa Rica
- 5Clima Soluciones S.A.S, Bogota, Colombia
- 6Ministerio de Ganadería, Agricultura y Pesca de Uruguay, Montevideo, Uruguay
- 7Department of Animal Husbandry, Universidad Nacional Agraria La Molina, Lima, Peru
- 8Animal Production Department, Instituto Nacional de Tecnología Agropecuaria INTA, Balcarce, Argentina
- 9Faculty of Veterinary Medicine and Animal Science, University of Yucatan, Mérida, Mexico
- 10Institute of Biological, Environmental and Rural Sciences, Aberystwyth University, Aberystwyth, United Kingdom
- 11Agricultural Innovation and Technology Transfer (AITTC), Mohammed VI Polytechnic University (UM6P), Benguerir, Morocco
Livestock production is a very relevant source of income and agricultural greenhouse gas (GHG) emissions in Colombia, Brazil, Argentina, Costa Rica, Uruguay, Mexico, and Peru. Several management and technological options with enteric methane mitigation potential have been evaluated and their scaling is anticipated to contribute toward achieving GHG emission reduction targets in the framework of the Paris Agreement. Yet, widespread adoption of promising mitigation options remains limited, raising questions as to whether envisaged emission reduction targets are achievable. Using findings from local studies, we explore the mitigation potentials of technologies and management practices currently proposed to mitigate enteric methane emissions from cattle production systems in the higher emitting countries of Latin America. We then discuss barriers for adopting innovations that significantly reduce cattle-based enteric methane emissions and the major shifts in policy and practice that are needed to raise national ambitions in the high emitting countries. Using the latest science and current thinking, we provide our perspective on an inclusive approach and re-imagine how the academic, research, business and public policy sectors can support and incentivize the changes needed to raise the level of ambition and achieve sustainable development goals (SDG), considering actions from the farm to the national scale.
Introduction
Cattle production is a pivotal source of income for Latin American countries, where a combination of large water reserves and vast natural resources create a conducive environment for animal husbandry. The importance of cattle production in the economic development of Colombia, Brazil, Argentina, Costa Rica, Uruguay, Mexico, and Peru is unambiguous. For instance, in Uruguay, about 11.3 million cattle utilize 13.3 million ha (Aguirre, 2018). Consequently, the cattle sector contributes 6% of national GDP and 28% of agricultural GDP (FAO UNDP, 2017). In Colombia, about 26.4 million cattle utilize ~37 million ha (Federación Colombiana de Ganaderos (Fedegan), 2018). Additionally, cattle rearing contributes 1.4% of national GDP and 21.8% of agricultural GDP. In Costa Rica, the national herd comprises 1.5 million cattle raised on 1.04 million ha and contributes 1.8% of national GDP and 33% of agricultural GDP (OECD, 2017). In Argentina, the national herd comprises about 53.9 million cattle on 110 million ha. It contributes 3.04% of national GDP (Dirección Nacional de Sanidad Animal- Servicio Nacional de Sanidad y Calidad Agroalimentaria (DNSA-SENASA), 2019) and 38% of agricultural GDP (OECD, 2018a). In Brazil, the cattle sector contributes 6.8% of national GDP and 30% of agricultural GDP from a herd size of 214.8 million cattle raised on 168 million ha (FAOSTAT, 2017). Mexico's cattle herd of 33.5 million (Servicio de Información Agroalimentaria y Pesquera (SIAP), 2019), is distributed around half the national territory (197 million ha). It contributes 1.6% of national GDP and 43% of agricultural GDP (OECD, 2018b). In Peru, about 5.5 million cattle are raised on 18.7 million ha of land and contribute 3.1% of national GDP and 34% of agricultural GDP.
Despite its economic importance, the cattle sector is also a major source of GHG emissions, particularly as enteric methane emissions (Table 1). Reconciling the goals of benefiting from business and livelihood opportunities associated with cattle production while reducing GHG emissions associated with cattle production is a challenge that regional governments are grappling with. This is important considering national commitments in the Paris Agreement of the United Nations Framework Convention on Climate Change (UNFCCC) and the Sustainable Development Goals (SDGs). In this paper, we present our thoughts on whether achieving the desired reductions in enteric methane emissions is possible, and discuss the barriers and changes needed to advance toward achieving GHG emission reduction targets set under the Paris Agreement and potential contribution to the SDGs.
Table 1. National areas dedicated to cattle production, GHG emissions and proportion of GHG emissions associated with cattle raising and GHG emission reduction in seven countries of Latin America.
Previous studies have shown that emission reduction ambitions submitted under the Paris Agreement would lead to global GHG emission reductions of 52–58 GtCO2eq yr−1 by 2030. Unfortunately, this level of emission reductions will not limit global warming to 1.5°C (IPCC, 2018). Therefore, to raise the levels of ambition in terms of GHG emission reductions, more actions need to be considered by all economic sectors, including the cattle sector. The question then is whether, for the cattle sector in Latin America, ambition can be raised using current management and technological options. By focusing on key studies conducted in seven target Latin American countries, we observed that tested mitigation and technology options might have the potential to reduce absolute GHG emissions (g per day), emission yields [g per kg of dry matter intake (DMI)] or emission intensities [g per kg of live weight (LW) gain] from cattle systems (Table 2).
Most of the studies shown in Table 2 demonstrate the possibility of reducing enteric methane emissions through dietary changes. However, because diet-based absolute enteric methane emission reductions have only been reported in a very limited number of studies, more options are likely to be identified with further research. In the meantime, improved herd management (e.g., to reduce the number of unproductive cattle) may be a more immediate approach to raise the level of ambition (Zhang et al., 2017). In addition, considering that other studies conducted in the region only report a reduction in emission intensities (see Table 2), increasing cattle numbers, as is normally the ambition at both individual farmer and national government levels, will increase incomes and definitively increase absolute emissions, unless feed options that can reduce absolute methane emissions can be identified and adopted at scale.
Numerous studies have evaluated the effects of various feed additives on methane emissions that might be of benefit to Latin American cattle producers. The use of plants containing condensed tannins has been shown to effectively reduce enteric methane emissions in cattle (e.g., Grainger et al., 2009; Piñeiro-Vázquez et al., 2018; Stewart et al., 2019), although the effect is dependent on the plant species used (Beauchemin et al., 2007) and care must be taken to prevent a reduction in diet digestibility and therefore animal productivity. However, offer potential to reduce enteric methane emissions in Latin American countries. Feeding fat and oils (e.g., Beauchemin and McGinn, 2006; Grainger and Beauchemin, 2011) offers potential to reduce enteric methane emissions and methane yields, but high concentrations of free fat (above about 6% of DMI) can have a detrimental effect on the rumen microbial population (Patra, 2013). Plant-derived essential oils have been shown to reduce methane emissions from ruminant livestock, but their mode of action is complex and poorly understood (Cobellis et al., 2016), and cost and availability limit their use. Feeding nitrate (Veneman et al., 2015) can lead to substantial reductions in methane emissions but is of limited practical value because of its potential toxic effects. Two recent novel feed additives, offered by private companies, are 3-NOP (Bovaer®, DSM Nutritional Products) and Mootral® (Mootral SA, Rolle, Switzerland) and are also of potential interest. Cattle supplemented with an average of 1.6 g 3-NOP/d enabled methane emissions reductions of between 23 and 33% (Kim et al., 2019; Van Wesemael et al., 2019). Similarly, inclusion of Mootral® in the diet at a rate of 3% of DMI showed a methane reduction of between 20 and 38% (Roque et al., 2019b). Additionally, the use of Asparagopsis spp., natural macroalgae used as a diet supplement, has demonstrated potential to reduce methane emissions; inclusion rates of 0.5% of DMI in dairy cow diets led to methane emission reductions of 26.4% without compromising milk yield or feed intake. Increasing the dietary inclusion rate to 1% of DMI resulted in reductions of 67.2% methane emissions (Roque et al., 2019a).
Plant breeding has long been used to improve the feeding value of forage crops and thus increase livestock productivity (Castor and Vogel, 1999). Until relatively recently, breeding targets have focused on plant yield and persistency, with nutritional value being mainly assessed as dry matter digestibility (Castor and Vogel, 1999). However, in the last 20 years or so breeding programs have started to consider other nutritional parameters that aim to reduce the environmental footprint of livestock production (Kingston-Smith et al., 2012). Tropical grass breeding is complicated by the apomictic reproduction of many of the commercially important forage species (Jank et al., 2011), although apomixis also offers a number of advantages for crop improvement (Miles, 2007). The use of improved forage species can contribute to a reduction in the environmental footprint of cattle production (Soteriades et al., 2018), but the development of forage species that can contribute to reduced emissions intensities does not automatically lead to their uptake by cattle producers.
Mitigation options such as the use of feed additives and improved forage germplasm offer an interesting way to reduce enteric methane emissions. Known responses allow for the inclusion of feed-based mitigation actions in national GHG inventories and also for setting up systems for monitoring, reporting and verifying (MRV) emission reductions. The national GHG inventories and MRV systems make it possible to connect mitigation actions with the quantification of progress in policy implementation.
Scaling Challenges
Despite the availability of promising mitigation options (such as silvopastoral systems, improved pastures and feed additives) for the cattle sector in Latin America, their adoption by farmers is still limited by multiple factors (Ruiz et al., 2016; Bravo et al., 2018; Charry et al., 2018; Enciso et al., 2018). To achieve the required scale there is a need to ensure that farmers have access to inputs, capital and information. Formal grass and legume seed sale systems are underdeveloped in most Latin American countries limiting the purchase of planting material or the number of varieties available. Since the establishment of more sustainable technologies (i.e., silvo-pastoral systems) involves high initial costs, under capital scarce conditions formal credit systems become essential. However, in most Latin American countries, no specific credit options exist for such purposes, leaving many (and especially small- and medium-scale) producers with scarce financial resources and without opportunities for implementing mitigation options. A differentiation of meat and milk products derived from environmentally friendly production systems (e.g., Charry et al., 2019) or payments for ecosystem services could help in sourcing capital for investing in mitigation options, but efforts in that direction are still scarce and have yet to be proven as applicable at a large scale. Although the scientific community is generating valuable information on different mitigation options, it is not guaranteed that this information reaches the final users (cattle producers), especially if it is not being disseminated in a way that it is understandable to them. In addition, extension systems are weakly developed and technical assistance is scarce, coordination is usually weak among the service providers and different concepts of mitigation options being disseminated might confuse the policy makers, extension officers, and farmers. Currently, technical assistance often stops after selling an input (e.g., seeds) and does not include (post-) establishment support, leading in many cases to a wrong application of promising alternatives, negative experiences, disappointment, and a negative image of the technologies within and beyond farming communities.
In addition, new regulations aimed at formalizing the livestock sector (e.g., Decree 1500/2007 in Colombia; Díaz and Burkart, 2019) may be counterproductive (e.g., in Colombia, formal slaughtering facilities were shut down without providing alternatives, resulting in clandestine slaughtering), and can make mitigation options less attractive to producers since in an informal value chain few incentives exist to differentiate products and implement on-farm improvements. When looking at cultural and behavioral factors, many livestock producers in Latin America prefer traditional over more technical and sustainable production systems for reasons of simplicity and risk aversion. In order to overcome this barrier and to find entry points with those producers, the dissemination of information on the economic, social, and environmental benefits of mitigation options becomes even more critical. For both the dissemination of information and policy formulation, it is likewise important to understand how livestock producers make decisions, i.e., regarding the adoption of technologies and mitigation strategies, and how their decision-making process is influenced by e.g., trust (in the information provided or in its sources), risks, social networks and socio-cultural contexts. Although this is a growing field of research with interesting approaches (e.g., Robert et al., 2016; Singh et al., 2016), evidence has so far mainly been provided for agricultural (e.g., Stuart et al., 2014; de Sousa et al., 2018; Azadi et al., 2019; Gatto et al., 2019) and non-bovine livestock production (e.g., Jones et al., 2013; Ambrosius et al., 2019; Hidano et al., 2019), and only to a limited extent for (bovine) livestock production in Latin American countries (e.g., Martínez-García et al., 2013; Rossi Borges and Oude Lansink, 2016). This indicates a knowledge gap which needs to be addressed in order to assure a more widespread adoption of mitigation strategies. This brief description of scaling challenges suggests that even when the right management and technological options have been identified, there is a need to explore new and holistic mechanisms for effective communication and adoption at system level for achieving impact at a larger scale. Policymakers, in that regard, should aim to enact policies adapted to the underlying farmer decision-making context.
As described in the previous section, besides silvopastoral and improved pasture systems and management, other technologies such as feed additives can help to reduce methane emissions in livestock production. Although they seem to be promising alternatives for effectively reducing methane emissions, their suitability needs to be evaluated for the Latin American context (especially for open grazing systems). In beef-cattle grazing systems, it might be difficult to apply the required doses to animals in the field and ensure proper intake of the active compounds, since the animals move around freely while they are not being kept indoors. In dual-purpose and intensified milk production systems, the application seems to be easier. At a first glance, feed additives seem to be a less costly mitigation option than the implementation of e.g., silvopastoral systems but detailed cost-benefit analyses for the Latin American context, comparing feed additives with other mitigation options, would be needed for providing clear information for decision-making at the farm level. Measuring, reporting and verifying the reduction of enteric methane emissions and the definition of payments for ecosystem services is likely to be easier (i.e., imputation of methane emission reduction by effective intake of the additive) when using feed additives in a determined quantity, than under grazing conditions in a silvopastoral or improved pasture system where the animals move around freely and have different forage consumption patterns and preferences. This makes feed additives an interesting additional mitigation option that should be considered in future studies, as well as in the implementation of projects and public policies related to GHG mitigation in the Latin American livestock sector.
Targeted Policies
Latin America has a significant opportunity to accelerate the transformation of its cattle sector through a wide implementation of novel technological options, such as the use of alternative feed options (Chirinda et al., 2017). However, such options require the decisive actions and support of governments at local and national levels and the engagement of both the private sector and all key local institutions (Serna et al., 2017). Currently, there are limited farm level climate change mitigation actions as farmers, as well as policy makers, have to manage potential trade-offs between climate change mitigation and socio-economic costs such as decreased food availability (Havlík et al., 2014). We contend that systemic and coordinated immediate science-based actions will contribute to the achievement of climate change goals. In addition, there is a need for robust and effective policies targeting both the demand and supply-side of cattle value chains (Scherer and Verburg, 2017).
Although policies are key (e.g., national low carbon development plans and Nationally Appropriate Mitigation Actions), cattle producers need to play their part to transform the sector into an active contributor of GHG emissions reduction in the region. By combining policies that facilitate short-term efficiency gains with solution-oriented mindsets amongst researchers, livestock stakeholders and farmers, we may be able to leverage significant changes for the Latin American cattle sector. Challenges remain regarding widespread adoption of proven technologies due to barriers to implementation such as cultural issues, access to finance, lack of private investment, and traditional mind-sets that are often misaligned to current realities. There is an important opportunity to bring behavioral and social sciences to work together in addressing such challenges in order to acquire an in-depth understanding of crucial factors that prevent the adoption of low emissions technologies (e.g., Jones et al., 2013; Martínez-García et al., 2013; Stuart et al., 2014; Rossi Borges and Oude Lansink, 2016; de Sousa et al., 2018; Azadi et al., 2019; Gatto et al., 2019).
Clear public policies focused on GHG mitigation in cattle production systems are pivotal for the success of national mitigation actions. It may be possible to enforce several mitigation actions at the farm level, but public or private farmer support services are crucial for supporting the implementation of new technologies. Moreover, acknowledging that countries are committed to contribute to the Paris Agreement and the SDGs is crucial (Kanter et al., 2016). A sustainable cattle production would contribute to various SDGs such as: (i) Climate Action (SDG 13) limiting GHG emissions; (ii) Life on Land (SDG 15) reducing deforestation, and (iii) Zero Hunger (SDG 2) through the increase in productivity and income of cattle producers. However, as indicated above, an increase in cattle production through increased animal numbers would result in increased absolute methane emissions unless efficiency of production is also increased. Policy development, therefore, must take into account ways of improving cattle productivity that lead to reduced emissions intensities, for example using better diets to increase growth rates and increase stocking densities to allow less land to be used for a certain level of productivity. Better fed animals are faster growing, healthier, and produce lower GHG emissions per kg of beef or milk produced.
Knowledge and Experience Sharing
To achieve the set ambitions, existing knowledge, experiences, and expertise should be continuously harnessed to build technical and research capacities in the region. Concurrently, to reduce experimental costs, there is a need to promote south-south knowledge exchange as well as sharing of analytical infrastructure (Rosenstock et al., 2016). This, together with increased research and development funding, will ensure that more promising options for reducing enteric methane are discovered, identified, tested and promoted (Gerber et al., 2013). This is important as it appears that both a lack of understanding of technical and management options to reduce GHG emissions, scaling mechanisms and financing are challenges that generally limit progress toward ambitious climate change mitigation targets (Brown et al., 2008). Yet, through knowledge and experience sharing, countries can learn from each other and thus jointly progress. Such exchanges should also include lessons learned and experiences that could provide insights on institutional mechanisms that can enable change at different scales and by different stakeholders.
Concluding Remarks
Considering cattle only as a large source of GHG emissions would be an incomplete assessment. Their contribution to food production and rural economies are just two of the other dimensions that need to be considered. However, it is also undeniable that cattle is a major contributor to GHG emissions from the AFOLU sector for most Latin American countries and it would be practically impossible to achieve national emission reduction targets without considering significant reductions from the cattle sector of Latin America. A range of technologies and agronomic practices exist to improve farm level efficiency. A real challenge is to increase productivity without also increasing methane emissions. From our perspective, achieving the desired reductions in enteric methane emissions is feasible but there is a need to consider a set of high leverage actions to increase access and adoption of novel technological options and incentivize behavioral change.
Data Availability Statement
All datasets generated for this study are included in the article/supplementary material.
Author Contributions
JA was responsible for guiding the entire process of drafting and analyzing national goals, as well as completing the next steps of research in the area of GHG mitigation in livestock production. AR was in charge of collecting information sent from all countries, summarizing, analyzing, and ordering it in the paper, as well as collaborating in the search for additional information. AL and DM-B were in charge of guiding the meaning that the perspective paper would have from the political-administrative point of view. JK-V, PR, CG, WO, MC, AB, and CT were the researchers in charge of collecting information on livestock production, greenhouse gas emissions, mitigation goals, and mitigation strategies of the countries of Mexico, Argentina, Peru, Uruguay, Costa Rica, Brazil, and Colombia, respectively. SB was responsible for carrying out the socioeconomic analysis and contributing to the perspectives that GHG mitigation research should have in Latin America. JM was responsible for giving a logical order to the brief, as well as providing tools for presenting the results of the review. NC was responsible for consolidating national mitigation objectives in all countries and generating a logical order in presenting the results of the review.
Funding
This work was implemented as part of the CGIAR Research Program on Climate Change, Agriculture and Food Security (CCAFS), which is carried out with support from CGIAR Fund Donors and through bilateral funding agreements. For details please visit https://ccafs.cgiar.org/donors. The views expressed in this document cannot be taken to reflect the official opinions of these organisations. In addition, this work was also done as part of the Livestock CRP. We gratefully acknowledge funding from Biotechnology and Biological Sciences Research Council project grants UK—CIAT Joint Centre on Forage Grasses for Africa (BBS/OS/NW/000009), RCUK-CIAT Newton Fund—Towards climate-smart forage-based diets for Colombian livestock (BB/R021856/1), and Advancing sustainable forage-based livestock production systems in Colombia (CoForLife) (BB/S01893X/1) and the UK Research and Innovation (UKRI) Global Challenges Research Fund (GCRF) GROW Colombia grant via the UK's BBSRC (BB/P028098/1).
Conflict of Interest
CT was employed by the company Clima Soluciones S.A.S., which is a consultancy firm that was hired by CIAT to collect and revise information regarding NDC commitments by Latin American countries that was then included in the paper.
The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Acknowledgments
We thank all donors that globally support the work of the CRP programs through their contributions to the CGIAR system. We openly thank Karla Sanabria for her collaboration with literature review during her internship at CCAFS.
References
Aguirre, E. (2018). “Evolución reciente de la productividad ganadera en Uruguay (2010-17). Metodología y primeros resultados,” in Anuario OYPA 2018 (Montevideo: Ministerio de Ganadería, Agricultura y Pesca (MGAP)), 457–70. Available at: http://www.mgap.gub.uy/sites/default/files/34_anuario_2018_-_evolucion_productividad_ganadera.pdf (accessed November 7, 2019).
Alvarado, V. I., Medrano, J. L., Haro, J. A., Castro, J., Dickhoefer, U., and Gómez, C. A. (2019). “Methane emission from dairy cows in cultivated and native pastures in High Andes of Peru,” in 7th International Greenhouse Gas and Animal Agriculture Conference (Foz do Iguaçu).
Ambrosius, F. H. W., Hofstede, G. J., Bokkers, E. A. M., Bock, B. B., and Beulens, A. J. M. (2019). The social influence of investment decisions: a game about the Dutch pork sector. Livestock Sci. 220, 111–122. doi: 10.1016/j.livsci.2018.12.018
ApexBrasil (2018). Brazil's Contribution to the Challenge of Sustainable Global Supply. Available online at: http://www.apexbrasil.com.br/uploads/FS-04-PxP2A_22May18.pdf (accessed November 7, 2019).
Azadi, Y., Yazdanpanah, M., and Mahmoudi, H. (2019). Understanding smallholder farmers' adaptation behaviors through climate change beliefs, risk perception, trust, and psychological distance: evidence from wheat growers in Iran. J. Environ. Manage. 250:109456. doi: 10.1016/j.jenvman.2019.109456
Beauchemin, K. A., and McGinn, S. M. (2006). Effects of various feed additives on the methane emissions from beef cattle. Int. Congress Ser. 1293, 152–155. doi: 10.1016/j.ics.2006.01.042
Beauchemin, K. A., McGinn, S. M., Martinez, T. F., and McAllister, T. A. (2007). Use of condensed tannin extract from quebracho trees to reduce methane emissions from cattle. J. Anim. Sci. 85, 1990–1996. doi: 10.2527/jas.2006-686
Bravo, A., Enciso, K., Hurtado, J. J., del Cairo, J. R., Jäger, M., Charry, A., et al. (2018). Estrategia sectorial de la cadena de ganadería doble propósito en Guaviare, con enfoque agroambiental y cero deforestación. Publicación CIAT No. 453. Cali: Centro Internacional de Agricultura Tropical (CIAT). Available online at: https://hdl.handle.net/10568/91289 (accessed November 14, 2019).
Brown, M. A., Chandler, J., Lapsa, M. V., and Sovacool, B. K. (2008). Carbon Lock-in: Barriers to Deploying Climate Change Mitigation Technologies. U. S. C. C. T. Program. Oak Ridge, TN: Oak Ridge National Laboratory.
Castor, M. D., and Vogel, K. P. (1999). Accomplishments and impact from breeding for increased forage nutritional value. Crop Sci. 39, 12–20. doi: 10.2135/cropsci1999.0011183X003900010003x
Chacón Navarro, M., Reyes Rivero, C., and Segura Guzmán, J. (2015). Estrategia para la ganadería baja en carbono en Costa Rica. Informe final, estrategia y plan de acción. Available online at: http://www.mag.go.cr/bibliotecavirtual/L01-11006.pdf (accessed November 14, 2019).
Charry, A., Jäger, M., Enciso, K., Romero, M., Sierra, L., Quintero, M., et al. (2018). Cadenas de valor con enfoque ambiental y cero deforestación en la Amazonía colombiana – Oportunidades y retos para el mejoramiento sostenible de la competitividad regional. CIAT Políticas en Síntesis No. 41. Cali: Centro Internacional de Agricultura Tropical (CIAT), 10. Available online at: https://hdl.handle.net/10568/97203 (accessed November 13, 2019).
Charry, A., Narjes, M., Enciso, K., Peters, M., and Burkart, S. (2019). Sustainable intensification of beef production in Colombia - chances for product differentiation and price premiums. Agric. Food Econ. 7:22. doi: 10.1186/s40100-019-0143-7
Chirinda, N., Arenas, L., Loaiza, S., Trujillo, C., Katto, M., Chaparro, P., et al. (2017). Novel technological and management options for accelerating transformational changes in rice and livestock systems. Sustainability 9:1891. doi: 10.3390/su9111891
Cobellis, G., Trabalza-Marinuccia, M., and Yu, Z. (2016). Critical evaluation of essential oils as rumen modifiers in ruminant nutrition: a review. Sci. Total Environ. 545–546, 556–568. doi: 10.1016/j.scitotenv.2015.12.103
de Sousa, K., Casanoves, F., Sellare, J., Ospina, A., Suchini, J. G., Aguilar, A., et al. (2018). How climate awareness influences farmers' adaptation decisions in Central America? J. Rural Stud. 64, 11–19. doi: 10.1016/j.jrurstud.2018.09.018
Díaz, M. F., and Burkart, S. (2019). Evolution of Public Policies Related to the Cattle and Dairy Sector in Colombia: Tension between Tradition and Modernity. CIAT Policy Brief No. 42. Cali: International Center for Tropical Agriculture (CIAT), 6. Available online at: https://hdl.handle.net/10568/100672 (accessed November 10, 2019).
Dini, Y., Gere, J. I., Cajarville, C., and Ciganda, V. (2018). Using highly nutritious pastures to mitigate enteric methane emissions from cattle grazing systems in South America. Anim. Product. Sci. 58, 2329–2334. doi: 10.1071/AN16803
Dirección Nacional de Sanidad Animal- Servicio Nacional de Sanidad y Calidad Agroalimentaria (DNSA-SENASA) (2019). Distribución de Existencias Bovinas por Categoría - Marzo 2019. Argentina. Available online at: http://www.abc-consorcio.com.ar/Estadisticas/detalle/283/existencias_de_bovinos_estables_a_marzo_de_2019.html (accessed November 14, 2019).
Enciso, K., Bravo, A., Charry, A., Rosas, G., Jäger, M., Hurtado, J. J., et al. (2018). Estrategia sectorial de la cadena de ganadería doble propósito en Caquetá, con enfoque agroambiental y cero deforestación. Publicación CIAT No. 454. Cali: Centro Internacional de Agricultura Tropical (CIAT), 125. Available online at: https://hdl.handle.net/10568/91981 (accessed October 21, 2019).
FAO UNDP (2017). Integrating Agriculture in National Adaptation Plans: Uruguay Case Study. Rome. Available online at: www.fao.org/in-action/naps (accessed September 18, 2019).
FAOSTAT (2017). Commodities by Country. Available online at: http://www.fao.org/faostat/en/#rankings/commodities_by_country (accessed November 14, 2019).
Federación Colombiana de Ganaderos (Fedegan) (2018). Cifras de referencia del sector ganadero colombiano. Available online at: https://www.fedegan.org.co/estadisticas/ (accessed November 14, 2019).
Gatto, P., Mozzato, D., and Defrancesco, E. (2019). Analysing the role of factors affecting farmers' decisions to continue with agri-environmental schemes from a temporal perspective. Environ. Sci. Policy 92, 237–244. doi: 10.1016/j.envsci.2018.12.001
Gaviria Uribe, X., Bolívar Vergara, D. M., Chirinda, N., Arango, J., and Barahona Rosales, R. (2019). “Enteric methane emissions of zebu steers fed with tropical forages of contrasting nutritional value,” in TropenTag 2019, September 18-20 2018, Kassel: International Center for Tropical Agriculture (CIAT), 1. Available online at: https://hdl.handle.net/10568/103643 (accessed August 25, 2019).
Gerber, P. J., Steinfeld, H., Henderson, B., Mottet, A., Opio, C., Dijkman, J., et al. (2013). Tackling Climate Change through Livestock – A Global Assessment of Emissions and Mitigation Opportunities. Rome: Food and Agriculture Organization of the United Nations (FAO), 96.
Grainger, C., and Beauchemin, K. A. (2011) Can enteric methane emissions from ruminants be lowered without lowering their production? Anim. Feed Sci. Technol. 166–167, 308–320. doi: 10.1016/j.anifeedsci.2011.04.021
Grainger, C., Clarke, T., Auldist, M. J., Beauchemin, K. A., McGinn, S. M., Waghorn, G. C., et al. (2009). Potential use of Acacia mearnsii condensed tannins to reduce methane emissions and nitrogen excretion from grazing dairy cows. Can. J. Anim. Sci. 89, 241–251. doi: 10.4141/CJAS08110
Grupo de Trabajo Multisectorial de naturaleza temporal encargado de generar información técnica para orientar la implementación de las Contribuciones Nacionalmente Determinadas (GTM-NDC) (2018). Informe Final. Lima: GTM-NDC. Available online at: http://www.minam.gob.pe/cambioclimatico/wp-content/uploads/sites/127/2019/01/190107_Informe-final-GTM-NDC_v17dic18.pdfPA%C3%91OL.pdf (accessed November 14, 2019).
Havlík, P., Valin, H., Herrero, M., Obersteiner, M., Schmid, E., Rufinno, M. C., et al. (2014). Climate change mitigation through livestock system transitions. Proc. Natl. Acad. Sci. U.S.A. 111, 3709–3714. doi: 10.1073/pnas.1308044111
Hidano, A., Gates, M. C., and Enticott, G. (2019). Farmers' decision making on livestock trading practices: cowshed culture and behavioral triggers amongst New Zealand Dairy Farmers. Front. Vet. Sci. 7:130. doi: 10.3389/fvets.2019.00320/full
IDEAM PNUD, MADS, DNP, CANCILLERÍA. (2018). Segundo Informe Bienal de Actualización de Colombia a la Convención Marco de las Naciones Unidas para el Cambio Climático (CMNUCC). Bogotá, DC: IDEAM, PNUD, MADS, DNP, CANCILLERÍA, FMAM. Available online at: http://www.ideam.gov.co/documents/24277/77448440/PNUD-IDEAM_2RBA.pdf/ff1af137-2149-4516-9923-6423ee4d4b54 (accessed August 20, 2019).
Instituto Nacional de Carnes (INAC) (2017). Uruguay Beef & Lamb. Uruguay: From Nature to Table. Available online at: https://uruguayanmeats.uy/news/uruguay-from-nature-to-table (accessed November 14, 2019).
Instituto Nacional de Ecología y Cambio Climático (INECC) (2016). Inventario Nacional de Emisiones y Compuestos de Gases de Efecto Invernadero. Coordinación General de Cambio Climático y Desarrollo Bajo en Carbono, 39.
Instituto Nacional de Estadística e Informática (INEI) (2012). IV Censo Nacional Agropecuario – 2012.
IPCC (2018). An IPCC Special Report on the Impacts of Global Warming of 1.5°C Above Pre-industrial Levels and Related Global Greenhouse Gas Emission Pathways, in the Context of Strengthening the Global Response to the Threat of Climate Change, Sustainable Development, and Efforts to Eradicate Poverty, eds V. Masson-Delmotte, P. Zhai, H.-O. Pörtner, D. Roberts, J. Skea, P. R. Shukla, A. Pirani, W. Moufouma-Okia, C. Péan, R. Pidcock, S. Connors, J. B. R. Matthews, Y. Chen, X. Zhou, M. I. Gomis, E. Lonnoy, T. Maycock, M. Tignor, and T. Waterfield (Geneva: World Meteorological Organization).
Jank, L., Valle, C. B., and Resende, R. M. S. (2011). Breeding tropical forages. Crop Breed. Appl. Biotechnol. S1, 27–34. doi: 10.1590/S1984-70332011000500005
Jones, A. K., Jones, D. L., Edwards-Jones, G., and Cross, P. (2013). Informing decision making in agricultural greenhouse gas mitigation policy: a Best–Worst Scaling survey of expert and farmer opinion in the sheep industry. Environ. Sci. Policy 29, 46–56. doi: 10.1016/j.envsci.2013.02.003
Kanter, D. R., Schwoob, M. H., Baethgen, W. E., Bervejillo, J. E., Carriquiry, M., Dobermann, A., et al. (2016). Translating the Sustainable Development Goals into action: a participatory backcasting approach for developing national agricultural transformation pathways. Global Food Security 10, 71–79. doi: 10.1016/j.gfs.2016.08.002
Kim, S. H., Lee, C., Pechtl, H. A., Hettick, J. M., Campler, M. R., Pairis-Garcia, M. D., et al. (2019). Effects of 3-nitrooxypropanol on enteric methane production, rumen fermentation, and feeding behavior in beef cattle fed a high forage or high grain diet. J. Anim. Sci. 97, 2687–2699. doi: 10.1093/jas/skz140
Kingston-Smith, A. H., Marshall, A. H., and Moorby, J. M. (2012). Breeding for genetic improvement of forage plants in relation to increasing animal production with reduced environmental footprint. Animal 7, 79–88. doi: 10.1017/S1751731112000961
Martínez-García, C. G., Dorward, P., and Rehman, T. (2013). Factors influencing adoption of improved grassland management by small-scale dairy farmers in central Mexico and the implications for future research on smallholder adoption in developing countries. Livestock Sci. 152, 228–238. doi: 10.1016/j.livsci.2012.10.007
MCTIC (2016). Annual Estimates of Greenhouse Gas Emissions in Brazil. Available online at: http://www.mctic.gov.br/mctic/export/sites/institucional/arquivos/ASCOM_PUBLICACOES/estimativa_de_gases.pdf (accessed September 8, 2019).
Miles, J. W. (2007). Apomixis for cultivar development in tropical forage grasses. Crop Sci. 47, S238–S249. doi: 10.2135/cropsci2007.04.0016IPBS
Ministerio de Ambiente y Energía Instituto Meteorológico Nacional (MINAE). (2015). Inventario nacional de gases de efecto invernadero y absorción de carbono, 2012. Available online at: https://unfccc.int/files/national_reports/non-annex_i_parties/biennial_update_reports/application/pdf/ghg_inventory_report.pdf (accessed September 5, 2019).
Ministerio de Ganadería Agricultura y Pesca (MGAP). (2019). Anuario Estadístico Agropecuario 2019. Available online at: http://www.mgap.gub.uy/unidad-organizativa/oficina-de-programacion-y-politicas-agropecuarias/publicaciones/anuarios-diea (accessed September 15, 2019).
Ministerio de Vivienda Ordenamiento Territorial y Medio Ambiente (MVOTMA). (2017). Segundo informe bienal de actualización a la conferencia de las partes en la convención marco de las naciones unidas sobre el cambio climático. Available online at: http://euroclimaplus.org/intranet/_documentos/repositorio/02%20Bienal%20de%20Uruguay%20ante%20la%20Convenci%C3%B3n%20Marco%20sobre%20Cambio%20Clim%C3%A1tico_2017.pdf (accessed September 3, 2019).
Ministerio del Ambiente (MINAM) (2016). Inventario Nacional de Gases de Efecto Invernadero con año base 2012.
Molina, I. C., Donney's, G., Montoya, S., Rivera, J. E., Villegas, G., Chará, J., et al. (2015). La inclusión de Leucaena leucocephala reduce la producción de metano de terneras Lucerna alimentadas con Cynodon plectostachyus y Megathyrsus maximus. Livestock Res. Rural Dev. 27, 1–8. Available online at: http://www.lrrd.org/lrrd27/5/moli27096.html
Montenegro, J., Barrantes, E., and DiLorenzo, N. (2016). Methane emissions by beef cattle consuming hay of varying quality in the dry forest ecosystem of Costa Rica. Livestock Sci. 193, 45–50. doi: 10.1016/j.livsci.2016.09.008
MRE MCTIC, MMA, MAPA, MME, Embrapa, ABC, ME. (2019). Brazil's Third Biennial Update Report to the United Nations Framework Convention on Climate Change. Available online at: https://unfccc.int/sites/default/files/resource/2018-02-28_BRA-BUR3_ENG_FINAL.pdf (accessed September 3, 2019).
OECD (2017). Agricultural Policies in Costa Rica. Paris: OECD Publishing. doi: 10.1787/9789264269125-en
OECD (2018a). Agricultural Policies in Argentina. Paris: OECD Publishing. Available online at: http://www.oecd.org/officialdocuments/publicdisplaydocumentpdf/?cote=TAD/CA(2018)9/FINAL&docLanguage=En (accessed September 4, 2019).
OECD (2018b). Working Party on Agricultural Policies and Markets. Agricultural Policy Monitoring and Evaluation 2018 Part II. Developments in Agricultural Policy and Support by Country. Available online at: http://www.oecd.org/officialdocuments/publicdisplaydocumentpdf/?cote=TAD/CA/APM/WP(2018)9/FINAL&docLanguage=En (accessed September 2, 2019).
Patra, A. K. (2013). The effect of dietary fats on methane emissions, and its other effects on digestibility, rumen fermentation and lactation performance in cattle: a meta-analysis. Livestock Sci. 155, 244–254. doi: 10.1016/j.livsci.2013.05.023
Pereira, C. H., Patino, H. O., Hoshide, A. K., Abreu, D. C., Rotz, C. A., and Nabinger, C. (2018). Grazing supplementation and crop diversification benefits for southern Brazil beef: a case study. Agric. Syst. 162, 1–9. doi: 10.1016/j.agsy.2018.01.009
Piñeiro-Vázquez, A. T., Canul-Solís, J. R., Jiménez-Ferrer, G. O., Alayón-Gamboa, J. A., Chay-Canul, A. J., Ayala-Burgos, A. J., et al. (2018). Effect of condensed tannins of Leucaena leucocephala on rumen fermentation, methane production and population of rumen protozoa in heifers fed low-quality forage. Asian Aust. J. Anim. Sci. 31, 1738–1746. doi: 10.5713/ajas.17.0192
Piquer-Rodríguez, M., Baumann, M., Butsic, V., Gasparri, H. I., Gavier-Pizarro, G., Volante, J. N., et al. (2018). The potential impact of economic policies on future land-use conversions in Argentina. Land Use Policy 79, 57–67. doi: 10.1016/j.landusepol.2018.07.039
Ricci, P., and Aello, M. S. (2018). Potencial de reducción de emisiones de metano en un sistema de producción de carne pastoril de ciclo completo del Sudeste Bonaerense. En: Producción bovinos para carne (2013–2017) - Programa Nacional de Producción Animal. Ediciones INTA, Publicación Técnica n° 109, 31–35.
Ricci, P., Testa, M. L., Alonso-Ramos, S., Maglietti, C. S., Pavan, E., Juliarena, P., et al. (2018). “Reducción de la intensidad de emisiones de metano en respuesta a la suplementación energética en pastoreo,” in Revista Argentina de Producción Animal. Vol. 38, 341. Available online at: http://ppct.caicyt.gov.ar/index.php/rapa/article/view/13936/45454575758846
Robert, M., Dury, J., Thomas, A., Therond, O., Sekhar, M., Badiger, S., et al. (2016). CMFDM: a methodology to guide the design of a conceptual model of farmers' decision-making processes. Agric. Syst. 148, 86–94. doi: 10.1016/j.agsy.2016.07.010
Roque, B. M., Salwen, J. K., Kinley, R., and Kebreab, E. (2019a). Inclusion of Asparagopsis armata in lactating dairy cows' diet reduces enteric methane emission by over 50 percent. J. Clean. Product. 234, 132–138. doi: 10.1016/j.jclepro.2019.06.193
Roque, B. M., Van Lingen, H. J., Vrancken, H., and Kebreab, E. (2019b). Effect of Mootral —a garlic- and citrus-extract-based feed additive— on enteric methane emissions in feedlot cattle. Transl. Anim. Sci. 3, 1383–1388. doi: 10.1093/tas/txz133
Rosenstock, T. S., Sander, B. O., Butterbach-Bahl, K., Rufino, M. C., Hickman, J., Stirling, C., et al. (2016). “Introduction to the SAMPLES approach,” in Methods for Measuring Greenhouse Gas Balances and Evaluating Mitigation Options in Smallholder Agriculture, eds T. S. Rosenstock, M. Rufino, K. Butterbach-Bahl, L. Wollenberg, and M. Richards (Cham: Springer), 1–13. doi: 10.1007/978-3-319-29794-1_1
Rossi Borges, J. A., and Oude Lansink, A. G. J. M. (2016). Identifying psychological factors that determine cattle farmers' intention to use improved natural grassland. J. Environ. Psychol. 45, 89–96. doi: 10.1016/j.jenvp.2015.12.001
Ruiz, L. R., Burkart, S., Muñoz Quiceno, J. J., Enciso, K., Gutierrez Solis, J. F., Charry, A., et al. (2016). “Inhibiting factors and promotion strategies for increasing adoption levels of improved forages in cattle production,” in Tropentag 2016 “Solidarity in a Competing World Fair Use of Resources" September 18–21, 2016 (Vienna: Centro Internacional de Agricultura Tropical (CIAT)), 1. Available online at: https://hdl.handle.net/10568/77030 (accessed August 28, 2019).
Scherer, L., and Verburg, P. H. (2017). Mapping and linking supply- and demand-side measures in climate-smart agriculture. a review. Agron. Sustain. Dev. 37:66. doi: 10.1007/s13593-017-0475-1
Secretaría de Ambiente y Desarrollo Sustentable (SGAyDS) (2019). Informe Nacional de Inventario del Tercer Informe Bienal de Actualización de la República Argentina a la Convención Marco de las Naciones Unidas para el Cambio Climático (CMNUCC).
Serna, L., Escobar, D., Tapasco, J., Arango, J., Chirinda, N., Chacon, M., et al. (2017). Challenges and Opportunities for the Development of the Livestock NAMA in Colombia and Costa Rica. CCAFS Info Note. Wageningen: CGIAR Research Program on Climate Change, Agriculture and Food Security (CCAFS). Available online at: https://hdl.handle.net/10568/81300 (accessed October 15, 2019).
Servicio de Información Agroalimentaria y Pesquera (SIAP) (2019). Bovino carne y leche - producción ganadera 2006-2015. Ciudad de México, México: Secretaría de Agricultura, Ganadería, Desarrollo Rural, Pesca y Alimentación. Available online at: https://www.gob.mx/cms/uploads/attachment/file/165997/bovino.pdf (accessed November 14, 2019).
Singh, C., Dorward, P., and Osbahr, H. (2016). Developing a holistic approach to the analysis of farmer decision-making: Implications for adaptation policy and practice in developing countries. Land Use Policy 59, 329–343. doi: 10.1016/j.landusepol.2016.06.041
Sistema Nacional de Respuesta al Cambio Climático y Variabilidad (SNRCC) (2018). Avances en la implementación de la Política Nacional de Cambio Climático de Uruguay y programación de la NDC. Available online at: https://www.latincarbon.com/sites/default/files/2018/Workshop%204.pdf (accessed November 14, 2019).
Soteriades, A. D., Gonzalez-Mejia, A. M., Styles, D., Foskolos, A., Moorby, J. M., and Gibbons, J. M. (2018). Effects of high-sugar grasses and improved manure management on the environmental footprint of milk production at the farm level. J. Cleaner Product. 202, 1241–1252. doi: 10.1016/j.jclepro.2018.08.206
Stewart, E. K., Beauchemin, K. A., Dai, X., MacAdam, J. W., Christensen, R. G., and Villalba, J. J. (2019). Effect of tannin-containing hays on enteric methane emissions and nitrogen partitioning in beef cattle. J. Anim. Sci. 97, 3286–3299. doi: 10.1093/jas/skz206
Stuart, D., Schewe, R. L., and McDermott, M. (2014). Reducing nitrogen fertilizer application as a climate change mitigation strategy: understanding farmer decision-making and potential barriers to change in the US. Land Use Policy 36, 210–218. doi: 10.1016/j.landusepol.2013.08.011
UNFCCC (2016). First Revision of Its Nationally Determined Contribution, Republic of Argentina. Available online at: https://www4.unfccc.int/sites/ndcstaging/PublishedDocuments/Argentina%20First/Traducci%C3%B3n%20NDC_Argentina.pdf (accessed November 14, 2019).
Valencia-Salazar, S. S., Piñeiro-Vázquez, A. T., Molina-Botero, I. C., Lazos-Balbuena, F. J., Uuh-Narváez, J. J., Segura-Campos, M. R., et al. (2018). Potential of Samanea saman pod meal for enteric methane mitigation in in crossbred heifers fed low-quality tropical grass. Agric. For. Meteorol. 258, 108–116. doi: 10.1016/j.agrformet.2017.12.262
Van Wesemael, D., Vandaele, L., Ampe, B., Cattrysse, H., Duval, S., Kindermann, M., et al. (2019). Reducing enteric methane emissions from dairy cattle: Two ways to supplement 3-nitrooxypropanol. J. Dairy Sci. 102, 1780–1787. doi: 10.3168/jds.2018-14534
Veneman, J. B., Muetzel, S., Hart, K. J., Faulkner, C. L., Moorby, J. M., Perdok, H. B., et al. (2015). Does dietary mitigation of enteric methane production affect rumen function and animal productivity in dairy cows? PLoS ONE 10:e0140282. doi: 10.1371/journal.pone.0140282
Keywords: SDG targets, Paris agreement (COP 21), NDC, Latin America, enteric methane
Citation: Arango J, Ruden A, Martinez-Baron D, Loboguerrero AM, Berndt A, Chacón M, Torres CF, Oyhantcabal W, Gomez CA, Ricci P, Ku-Vera J, Burkart S, Moorby JM and Chirinda N (2020) Ambition Meets Reality: Achieving GHG Emission Reduction Targets in the Livestock Sector of Latin America. Front. Sustain. Food Syst. 4:65. doi: 10.3389/fsufs.2020.00065
Received: 16 November 2019; Accepted: 17 April 2020;
Published: 14 May 2020.
Edited by:
Todd Andrew Crane, International Livestock Research Institute, KenyaReviewed by:
Polly Joanna Ericksen, International Livestock Research Institute, KenyaDavid Kanter, New York University, United States
Copyright © 2020 Arango, Ruden, Martinez-Baron, Loboguerrero, Berndt, Chacón, Torres, Oyhantcabal, Gomez, Ricci, Ku-Vera, Burkart, Moorby and Chirinda. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Jacobo Arango, j.arango@cgiar.org