Further unlocking the potential of maize: Dual-purpose is the new purpose of the world’s most important cereal

In the field: Kenya

Maize field at Kampi ya Moto, Kenya (photo on Flickr by C Schubert/CCAFS).

September 2013 special issue of the scientific journal Field Crops Research describes research to improve, and make wider use of, dual-purpose maize (or corn) varieties, which are used for their stover — the stalk, leaves and other residue of the plant after the grain has been harvested — as well as for their grain. Among smallholder farmers in Africa and other developing regions, maize stover is a common, and critically important, supplementary feed for ruminant livestock.

The special journal issue was edited by edited by Elaine Grings, of South Dakota State University (and formerly of ILRI); Olaf Erenstein, of the International Maize and Wheat Improvement Center; and Michael Blümmel, of the International Livestock Research Institute (ILRI).

The following statements are excerpted from a synthesis paper written by the editors, which presents key findings in 12 papers about the potential for dual-purpose maize varieties to meet changing maize demands.

This special issue substantiates that dual-purpose maize varieties are technically feasible and have a large potential market, particularly in many emerging markets. The reported findings argue the case for continued investments in maize stover R&D and thus reigniting earlier dual-purpose crop research in general.

WatotoWeeding4A-74

Children weed a maize plot at Kampi ya Moto, Kenya (photo on Flickr by C Schubert /CCAFS).

Among the findings are the following.

‘Maize — or corn (Zea mays L.) — now is the most important global cereal in terms of production reflecting its versatility in use, including human food, animal feed and fodder, industrial products and biofuel.’

‘Despite being a versatile crop, maize production and maize breeding efforts over time have typically had a single-purpose orientation [on improving grain yields]. . . . Even smallholders within mixed maize-livestock systems typically focus on maize grain yield . . . , with maize stover as additional byproduct and benefit.’

There are prospects within the range of stover quality to increase fodder quality without compromising grain yield.

‘It is this potential of dual-purpose varieties that has reignited research interest and some of the research underlying this special issue. Indeed, despite earlier skepticism only a decade ago, substantial progress has been made in developing dual-purpose maize options for both grain and fodder purposes . . . .’

‘Maize germplasm differences in fodder quality can be exploited without compromising on grain yield.’

‘Confirmation of the relatively favorable feed value of maize stover vis-à-vis other coarse cereal residues — having at least par if not better feed quality traits compared to sorghum and millet, which have been the focus of prior dual-purpose crop improvement research and have been reported to contribute substantially to gross crop production values.’

‘Confirmation of being able to rely on a few key laboratory indicators . . .  as good proxies for feed quality . . . as this enhances the ease of screening for feed quality traits.’

‘From a livestock nutrition viewpoint, an increase in stover quantity is only useful (unless making stover cheaper) if livestock can respond with increased intake, which is stover quality dependent.’

Dairy cow on a Kenyan smallholding

 A dairy cow on one of Kenya’s many smallholder farms consumes maize stover, an important supplementary feed in East Africa (photo credit: ILRI).

Read the synthesis paper, as well as other papers, in this special issue of Field Crops Research 153 (2013) 107–112, edited by Elaine Grings, Olaf Erenstein and Michael Blümmel. The papers authored by ILRI scientists include the following.

Blümmel M, Grings E and Erenstein O 2013:
Potential for dual-purpose maize varieties to meet changing maize demands: Synthesis

Erenstein O, Blümmel M and Grings E 2013:
Potential for dual-purpose maize varieties to meet changing maize demands: Overview

Homann Kee-Tui S, Blümmel M, Valbuena D, Chirima A, Masikati P, Rooyen AF van and Kassie GT 2013:
Assessing the potential of dual-purpose maize in southern Africa: A multi-level approach

Anandan S, Khan AA, Ravi D, Sai Butcha Rao M, Reddy YR and Blümmel M 2013:
Identification of a superior dual purpose maize hybrid among widely grown hybrids in South Asia
and value addition to its stover through feed supplementation and feed processing

Ravi D, Khan AA, Sai Butcha Rao M and Blümmel M 2013:
A note on suitable laboratory stover quality traits for multidimensional maize improvement

Ramana Reddy Y, Ravi D, Ramakrishna Reddy C, Prasad KVSV, Zaidi PH, Vinayan MT and Blümmel M 2013:
A note on the correlations between maize grain and maize stover quantitative and qualitative traits
and the implications for whole maize plant optimization

Lukuyu BA, Murdoch AJ, Romney D, Mwangi DM, Njuguna JGM, McLeod A and Jama AN 2013:
Integrated maize management options to improve forage yield and quality on smallholder farms in Kenya

Ertiro BT, Twumasi-Afriyie S, Blummel M, Friesen D, Negera D, Worku M, Abakemal D and Kitenge K 2013:
Genetic variability of maize stover quality and the potential for genetic improvement of fodder value

Ertiro BT, Zeleke H, Friesen D, Blümmel M and Twumasi-Afriyie, S 2013:
Relationship between the performance of parental inbred lines and hybrids for food-feed traits in maize (Zea mays L.) in Ethiopia

Zaidi PH, Vinayan MT and Blümmel M 2012:
Genetic variability of tropical maize stover quality and the potential for genetic improvement of food-feed value in India

Vinayan MT, Babu R, Jyothsna T, Zaidi PH and Blümmel M 2013:
A note on potential candidate genomic regions with implications for maize stover fodder quality

Read about this special issue in the ILRI Clippings Blog:
Field Crops Research special issue on dual-purpose maize for food and feed, 15 Nov 2013.

Planet under pressure / A numbers game–but which numbers are the numbers that matter?

And growing

Population of the Earth on 26 September 2004, last day of a Fòrum Universal de les Cultures event in Barcelona, where this counter was and this photo was taken (image on Flickr by Daniel Daranas, horitzons inesperats).

Speaking on ‘Sustainable food systems for food security’, Marianne Banziger, a scientist at the CGIAR maize and wheat centre (CIMMYT), this afternoon gave a ‘Rank Lecture’ at the Planet Under Pressure Conference in London.

She began with a bald statistic: To meet the food security challenges converging over the next 50 years, she said, we will have to produce as much food as has been consumed over the entire history of humankind.

Things did not get better after that.

We can expect more food price hikes, she argued, like those the world experienced in 2008 and 2010. Those peaks were due to low stocks; food prices went up three-fold and food prices have never returned to 2006 levels.

A large part of the changing food situation, Banziger explained, is due to the many people in developing countries that are newly incorporating into their largely starch-based diets meat, milk and eggs. However, most people gaining a bit of disposable income for the first time and using it to buy animal-source foods are still consuming far less of these foods than people in rich countries.

Biofuels are complicating the situation further: some 40% of the US maize crop now goes to biofuel, which is more than what is produced for animal feed.

Food price increases push people back into poverty, she reminded her audience. As food prices increase, and people find food less and less affordable, the proportion of their consumption of staple crops increases. If we do not act, food and energy price inflation will exceed income growth of the poor—pushing them further into poverty.

Living on borrowed resources
What goes up must come down: As fertilizer prices go up, the profitability and yields of smallholder farmers in developing countries go down.

Some 300 million people in India and China are sustained with grain grown from the over-pumping of water (that is, water resources not renewed by rainfall).

Social unrest is likely to come back again and again; deforestation, water scarcity and human migration are all likely to increase,

We still have the time to act.
Science usefully provides us with options.

We could reduce our consumption of food. How many of us now recycle and conserve water? Reduce food wastage? Eat less meat? These actions reduce demand. Those people now climbing out of poverty have as much right as we do to eat well.

On the other hand, we could increase our production of food.

The more we delay investments in this, the steeper will be the challenges we face.

Among new opportunities for increasing productivity are use of precision agriculture and cell phones (for conducting financial transactions, buying crop and input insurance).

We should not make the same mistakes as in the past by focusing on higher productivity alone. Farmers also need to generate greater income, to build greater resilience to shocks, to conduct sustainable farming, and to access viable markets and value chains.

Eyes wide open
Closing the yield gap among today’s marginalized farmers will not be enough, Banziger said. Farmers in the Indo-Gangetic Plains now grow wheat for 700 million people. But the encroachment of heat on these plains is expected to reduce yields 20–30% by 2050.

We need to explore the untapped biodiversity of staple crops. Drought-tolerant maize varieties have succeeded in the past. We’re looking for heat tolerance in wheat. Will transgenics be needed? The challenges are extreme, so ‘we need to keep our eyes open’.

Catch 22
At the close of Banziger’s presentation, a population expert in the audience asked what he might have presumed to be a rhetorical question: Why had Banziger omitted all reference to reducing the human population as a main method of ensuring food security?

Banziger responded forthrightly: It is not the increasing numbers of people per se that is the greatest factor in our food challenges, she said. Rather, it is the great numbers of people who are escaping absolute poverty (especially in India, China and Southeast Asia), and who are improving the quality of their diets as they do so by adding animal-source and other highly nutritious foods to their daily meals.

The implications are that reducing the numbers of people on the planet will not solve our food problems if great numbers of those people that remain keep moving out of poverty–a trajectory that many of this conference’s delegates are spending their professional lives working to advance.

Read more about the Planet Under Pressure conference:
ILRI News Blog: Planet under pressure / Livestock under the radar, 26 Mar 2012.

 

 

New study warns that climate change could create agricultural winners and losers in East Africa

While predicting highly variable impacts on agriculture by 2050, experts show that with adequate investment the region can still achieve food security for all

Forage Diversity field on ILRI Addis campus

As African leaders prepare to present an ambitious proposal to industrialized countries for coping with climate change in the part of the world that is most vulnerable to its impacts, a new study points to where and how some of this money should be spent. Published in the peer-reviewed journal Agricultural Systems, the study projects that climate change will have highly variable impacts on East Africa’s vital maize and bean harvests over the next two to four decades, presenting growers and livestock keepers with both threats and opportunities.

Previous estimates by the study’s authors projected moderate declines in the production of staple foods by 2050 for the region as a whole but also suggested that the overall picture disguises large differences within and between countries. The new findings provide a more detailed picture than before of variable climate change impacts in East Africa, assessing them according to broadly defined agricultural areas.

‘Even though these types of projections involve much uncertainty, they leave no room for complacency about East Africa’s food security in the coming decades,’ said the lead author of the new study, Philip Thornton of the International Livestock Research Institute (ILRI), which is supported by the Consultative Group on International Agricultural Research (CGIAR). ‘Countries need to act boldly if they’re to seize opportunities for intensified farming in favored locations, while cushioning the blow that will fall on rural people in more vulnerable areas.’

The researchers simulated likely shifts in cropping, using a combination of two climate change models and two scenarios for greenhouse gas emissions, together with state-of-the-art models for maize and beans, two of the region’s primary staple foods.

In the mixed crop-livestock systems of the tropical highlands, the study shows that rising temperatures may actually favor food crops, helping boost output of maize by about half in highland ‘breadbasket’ areas of Kenya and beans to much the same degree in similar parts of Tanzania. Meanwhile, harvests of maize and beans could decrease in some of the more humid areas, under the climate scenarios used in the study. Across the entire region, production of both crops is projected to decline significantly in drylands, particularly in Tanzania.

‘The emerging scenario of climate-change winners and losers is not inevitable,’ said ILRI director general Carlos Seré. ‘Despite an expected three-fold increase in food demand by 2050, East Africa can still deliver food security for all through a smart approach that carefully matches policies and technologies to the needs and opportunities of particular farming areas.’

At the Seventh World Forum on Sustainable Development, held recently in Ouagadougou, Burkina Faso, African leaders announced a plan to ask the industrialized world to pay developing countries USD67 billion a year as part of the continent’s common negotiating position for December’s climate talks in Copenhagen.

The ILRI study analyzes various means by which governments and rural households can respond to climate change impacts at different locations. In Kenya, for example, the authors suggest that shifting bean production more to the cooler highland areas might offset some of the losses expected in other systems.

Similarly, Tanzania and Uganda could compensate for projected deficits in both maize and beans through increased regional trade. In the Common Market for Eastern and Southern Africa (COMESA), maize trade is already worth more than USD1 billion, but only 10 percent of it occurs within the region. As grain prices continue to rise in global markets, several East African countries will be well positioned to expand output of maize and beans for regional markets, thus reducing reliance on imports and boosting rural incomes.

Where crop yields are expected to decline only moderately because of climate change, past experience suggests that rural households can respond effectively by adopting new technologies to intensify crop and livestock production, many of which are being developed by various CGIAR-supported centres and their national partners.

Drought-tolerant maize varieties, for example, have the potential to generate benefits for farmers estimated at USD863 million or more in 13 African countries over the next 6 years, according to a new study carried out by the International Maize and Wheat Improvement Center (CIMMYT) and International Institute of Tropical Agriculture (IITA). Meanwhile, new heat-tolerant varieties of productive climbing beans, which are traditionally grown in highlands, are permitting their adoption at lower elevations, where they yield more than twice as much grain as the bush-type beans grown currently, according to Robin Buruchara of the International Center for Tropical Agriculture (CIAT).

In areas that face drastic reductions in maize and bean yields, farmers may need to resort to more radical options, such as changing the types of crops they grow (replacing maize, for example, with sorghum or millet), keeping more livestock or abandoning crops altogether to embrace new alternatives, such as the provision of environmental services, including carbon sequestration.

This latter option could become a reality under COMESA’s Africa Biocarbon Initiative, which is designed to tap the huge potential of the region’s diverse farmlands and other rural landscapes, ranging from dry grasslands to humid tropical forests, for storing millions of tons of carbon. The initiative offers African negotiators an appealing option in their efforts to influence a future climate change agreement.

‘If included in emissions payment schemes, this initiative could create new sources of income for African farmers and enhance their resilience to climate change,’ said Peter Akong Minang, global coordinator of the Alternatives to Slash-and-Burn (ASB) Programme at the World Agroforestry Centre. ‘Its broad landscape approach would open the door for many African countries to actively participate in, and benefit from, global carbon markets.’

‘Rural people manage their livelihoods and land in an integrated way that encompasses many activities,’ said Bruce Campbell, director of the CGIAR’s Challenge Program on Climate Change, Agriculture and Food Security. ‘That’s why they need integrated options to cope with climate change, consisting of diverse innovations, such as drought-tolerant crops, better management of livestock, provision of environmental services and so forth.’

How rapidly and successfully East African nations and rural households can take advantage of such measures will depend on aggressive new investments in agriculture, CGIAR researchers argue. According to a recent study by the International Food Policy Research Institute (IFPRI), it will take about USD7 billion annually, invested mainly in rural roads, better water management and increased agricultural research, to avert the dire implications of climate change for child nutrition worldwide.

About 40 per cent of that investment would address the needs of sub-Saharan Africa, where modest reductions projected for maize yields in the region as a whole are expected to translate into a dramatic rise in the number of malnourished children by 2050. Thornton’s projections probably underestimate the impacts on crop production, because they reflect increasing temperatures and rainfall changes only and not greater variability in the weather and growing pressure from stresses like drought and insect pests.

‘Farmers and pastoralists in East Africa have a long history of dealing with the vagaries of the weather,’ said Seré. ‘But climate change will stretch their adaptive capacity beyond its limits, as recent severe drought in the region has made abundantly clear. Let’s not leave rural people to fend for themselves but rather invest significantly in helping them build a more viable future.’

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About ILRI:
The Africa-based International Livestock Research Institute (ILRI) works at the crossroads of livestock and poverty, bringing high-quality science and capacity-building to bear on poverty reduction and sustainable development. ILRI is one of 15 centers supported by the Consultative Group on International Agricultural Research (CGIAR). It has its headquarters in Kenya and a principal campus in Ethiopia. It also has teams working out of offices in Nigeria, Mali, Mozambique, India, Thailand, Indonesia, Laos, Vietnam and China. www.ilri.org.

About the CGIAR: The CGIAR, established in 1971, is a strategic partnership of countries, international and regional organizations and private foundations supporting the work of 15 international Centers. In collaboration with national agricultural research systems, civil society and the private sector, the CGIAR fosters sustainable agricultural growth through high-quality science aimed at benefiting the poor through stronger food security, better human nutrition and health, higher incomes and improved management of natural resources. www.cgiar.org