Global climate change negotiators meet this week to tackle myriad issues, including how to reduce greenhouse gas emissions from agriculture and protect food and farming from worsening climate impacts.
But unheralded and behind COP23 headlines, governments, private companies, and scientists led by CGIAR are already developing and sharing life-saving innovations for farmers, particularly smallholders, who fight daily at the climate change frontlines.
Technology such as drought- and heat-tolerant maize, resistant crops and control practices to combat newly-emerging pests, insurance to recover from extreme or erratic weather, and more targeted use of nitrogen fertilizers are already being adopted in Africa and Asia to reduce agriculture’s footprint while improving farm resilience and productivity.
Click here to read a message by Elwyn Grainger-Jones, Executive Director, CGIAR System Organization, and Martin Kropff, Director General, CIMMYT (the International Maize and Wheat Improvement Center) describing these efforts and issuing a wake-up call for world leaders.
The CIMMYT maize germplasm bank holds 28,000 samples of unique maize genetic diversity that could hold the key to develop new varieties farmers need. Photo: Xochiquetzal Fonseca/CIMMYT.
EL BATAN, Mexico (CIMMYT) – Biodiversity is the building block of health for all species and ecosystems, and the foundation of our food system. A lack of genetic diversity within any given species can increase its susceptibility to stress factors such as diseases, pests, heat or drought for lack of the genetic variation to respond. This can lead to devastating consequences that include crop failures and extinction of species and plant varieties. Conserving and utilizing biodiversity is crucial to ensure the food security, health and livelihoods of future generations.
The 13th meeting of the Conference of the Parties (COP 13) to the Convention on Biological Diversity will be held in Cancún, Mexico, from December 5 to 17, 2016. Established in 1993 due to global concerns over threats to biodiversity and species extinctions, the Convention on Biological Diversity is an international, legally-binding treaty with three main objectives: the conservation of biological diversity; the sustainable use of the components of biological diversity; and the fair and equitable sharing of the benefits arising out of the utilization of genetic resources.
Mexico’s Secretariat of Agriculture (SAGARPA) has invited scientists from the International Maize and Wheat Improvement Center (CIMMYT) working with the MasAgro Biodiversidad (known in English as Seeds of Discovery, or SeeD) initiative to present at COP 13 on their work to facilitate the use of maize genetic diversity, particularly through a collection of tools and resources known as the “Maize Molecular Atlas.” The presentations will focus on how resources that have been developed can aid in the understanding of germplasm stored in genebanks and collections to enable better use.
As the region of origin and as a center of diversity for maize, Mexico and Mesoamerica are home to much of the crop’s genetic variation. Thousands of samples of maize from this and other important regions are preserved in the CIMMYT germplasm bank, in trust, for the benefit of humanity. The bank’s 28,000 maize seed samples hold diversity to develop new varieties for farmers to respond to challenges such as heat, disease and drought stress. However, information on the genetic makeup and physical traits of these varieties is often limited, making the identification of the most relevant samples difficult.
Native maize varieties, known as landraces, contain a broad amount of genetic diversity that could protect food security for future generations.
SeeD works to better characterize and utilize novel genetic diversity in germplasm banks to accelerate the development of new maize and wheat varieties for the benefit of farmers. The initiative has generated massive amounts of information on the genetic diversity of maize and wheat, as well as cutting-edge software tools to aid in its use and visualization. This information and tools are freely available as global public goods for breeders, researchers, germplasm bank managers, extension agents and others, but are even more powerful when they are integrated with different types and sets of data.
Developed by the SeeD initiative, the maize molecular atlas represents an unparalleled resource for those interested in maize genetic diversity.
“You can think of the maize molecular atlas like a satellite navigation system in your car,” said Sarah Hearne, a CIMMYT scientist who leads the project’s maize component. “Information that used to be housed separately, such as maps, traffic or the locations of police officers, gas stations, restaurants and hotels, are now brought together. It’s the same with the atlas. Having access to all of these data at once in an interlinked manner allows people to make better decisions, faster,” she said.
SeeD’s maize molecular atlas includes three main types of resources: data, such as maize landrace passport data (where it came from, when it was collected, etc.), geographic information system (GIS) -derived data (what the environment was like where maize was collected; rainfall, soils, etc.), genotypic data (genetic fingerprints of maize varieties) and available phenotypic data (information on how plants grow in different conditions); knowledge, (derived from data-marker trait associations; what bits of the genome do what); and tools, including data collection software (KDSmart), data storage and query tools (Germinate) and visualization tools (CurlyWhirly).
All of these resources are available through the SeeD website, where, when used together, they can increase the effective and efficient identification and utilization of maize genetic resources.
Interestingly, one of the first benefits of this initiative was for Mexican farmers. The efforts to better characterize the collection led to the identification of landraces that were resistant to Tar Spot, a disease that is devastating many farmers’ fields in Mexico and Central America. These landraces were immediately shared with farming communities while also being utilized in breeding programs. Smallholders in particular grow crops in diverse environmental conditions. They need diverse varieties. The understanding and use of biodiversity by researchers, breeders and farmers will be crucial to ensure the use of more and genetically diverse crops.
“With the atlas we now have the ability, with fewer resources, to interlink and query across different data types in one searchable resource,” Hearne said. This will allow breeders and researchers world-wide to hone in on the genetic and physical plant traits they are looking for, to more quickly identify and use novel genetic diversity to create improved varieties adapted to their specific needs. So far about 250 researchers and students from Mexico have participated in workshops and activities to begin using the new tools. With Mexico being a very important center of diversity for many species, agricultural and beyond, the same tools could be used for other species, here and abroad.
Hearne is looking forward to sharing information about MasAgro Biodiversidad and CIMMYT’s progress at COP 13, and is hopeful about the impacts the maize molecular atlas will have on biodiversity conservation.
“Conservation isn’t just preservation, it’s use. The molecular maize atlas enables us to better utilize the genetic resources we have, but also to better understand what diversity we may still need for our collection,” she said. “If you don’t know what you have, you don’t know what you need to preserve or look for. The work of the maize molecular atlas helps to address the underlying causes of biodiversity loss by raising awareness of the importance of these resources for sustainable food production while enabling researchers world-wide to use the information for assessing their own collections and generate more diverse varieties.”
SeeD is a multi-project initiative comprising: MasAgro Biodiversidad, a joint initiative of CIMMYT and the Mexican Ministry of Agriculture (SAGARPA) through the MasAgro(Sustainable Modernization of Traditional Agriculture) project; the CGIAR Research Programs on Maize (MAIZE CRP) and Wheat (WHEAT CRP); and a computation infrastructure and data analysis project supported by the UK’s Biotechnology and Biological Sciences Research Council (BBSRC). Learn more about the Seeds of Discovery project here.
Precision levelers are climate-smart machines equipped with laser-guided drag buckets to level fields so water flows evenly into soil, rather than running off or collecting in uneven land. This allows much more efficient water use and saves energy through reduced irrigation pumping, compared to traditional land leveling which uses animal-powered scrapers and boards or tractors. It also facilitates uniformity in seed placement and reduces the loss of fertilizer from runoff, raising yields. (Photo: CIMMYT)
As world leaders meet in Paris this week to agree on greenhouse gas emission targets, we in the field of agricultural research have a powerful contribution to make, by producing both robust estimates of the possible effects of climate change on food security, and realistic assessments of the options available or that could be developed to reduce agriculture’s contribution to greenhouse gas emissions.
Agriculture is estimated to be responsible for about a fifth of global greenhouse gas emissions, and this share is increasing most rapidly in many developing countries; it may even increase as fossil fuels become scarcer and phased out in other sectors.
The solution being put forward today is climate-smart agriculture (CSA), which involves three components: adaptation, mitigation, and increased productivity. Adaptation is essential to cope with the impacts that cannot be avoided and to maintain and increase the global food supply in the face of resource constraints; mitigation can lessen but not prevent future climate changes.
Though CSA has been held up as an answer to the challenges presented by climate change, some would argue that it is no more than a set of agricultural best practices. Indeed, this is what lies at the heart of the approach.
In addition to making agriculture more efficient and resilient, the overall purpose remains to sustainably increase farm productivity and profitability for farmers. This is why over the last few years we have begun talking about the ‘triple win’ of CSA: enhanced food security, adaptation, and mitigation. But those who dismiss CSA as mere best practice ignore the value of seeing through the climate change lens, and guiding research to respond to expected future challenges.
To begin with, crop performance simulation and modeling, in combination with experimentation, has an important role to play in developing CSA strategies for future climates.
In a publication titled “Adapting maize production to climate change in sub-Saharan Africa,” several CIMMYT scientists concluded that temperatures in sub-Saharan Africa will likely rise by 2.1°C by 2050 based on 19 climate change projections. This is anticipated to have an extreme impact for farmers in many environments. Because it takes a long time to develop and then deploy adaptation strategies on a large scale, they warned, there can be no delay in our work.
Our insights into the causes and impacts of climate change lead us to important research questions. For example, how can farmers adopt practices that reduce the greenhouse gas footprint of agriculture while improving yield and resilience?
Colleagues at CIMMYT have challenged the idea that the practice of no-till agriculture (which does not disturb the soil and allows organic matter to accumulate) contributes significantly to carbon sequestration. I think it is important that we, as scientists, explore the truth and be realistic about where opportunities for mitigation in agriculture lie, despite our desire to present major solutions. It is also important to take action where we can have the greatest impact, for example by improving the efficiency of nitrogen fertilizer use.
Nitrous oxide emissions from agriculture have a climate change potential almost 300 times greater than carbon dioxide, and account for about 7% of the total greenhouse gas emissions of China. Improved nutrient management could reduce agricultural greenhouse gas emissions by the equivalent of 325 Mt of carbon dioxide in 2030. Overall, supply-side efficiency measures could reduce total agricultural emissions by 30%.
Some practices, such as laser land leveling, fall into both the adaptation and mitigation categories. Preparing the land in this way increases yields while reducing irrigation costs, the amount of water used, nutrients leached into the environment, and emissions from diesel-powered irrigation pumps.
Findings such as this offer real hope of reducing the severity of climate change in the future, and help us build a case for more investment in critical areas of agricultural research.
For climate-smart agriculture, the challenge of feeding more people and reducing emissions and environmental impact is not a contradiction but a synergy. We are improving our ability to predict the challenges of climate change, and proving that it is possible to greatly reduce agricultural emissions and contribute to global emission goals.
To face challenges such as climate change, we need high quality multi-disciplinary science combined with approaches to address problems at the complex systems level. Since my involvement in early large-scale studies, such as Modeling the Impact of Climate Change on Rice Production in Asia (CABI/IRRI, 1993), I am pleased to see that so much progress has been made in this regard and encouraged that our research is contributing to greater awareness of this vital issue and solutions to address it.
