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Eloise Phipps

Jun 122015
 
Photo: IITA

Growing cowpea pods.

Each year, millions of people in Senegal go hungry for several months, many surviving on no more than one meal a day. Locals call this time soudure – the hungry period. It typically lasts from June through to September, when previous winter and spring cereal supplies are exhausted and people wait anxiously for a bountiful autumn cereal harvest.

During this period, a bowl of fresh green cowpea pods once a day is the best that many people can hope for. Cowpeas are the first summer crop to mature, with some varieties ready to harvest in as little as 60 days.

While cowpeas provide valued food security in Africa, yields remain low. In Senegal, average cowpea yields are 450 kilograms per hectare, a mere 10–30 percent of their potential. This poor productivity is primarily because of losses due to insects and diseases, but is sometimes further compounded by chronic drought.

In 2007, the CGIAR Generation Challenge Programme (GCP) brought together a team of plant breeders and geneticists from Burkina Faso, Mozambique, Nigeria, Senegal and the USA to collaborate on cowpea. Their goal was to breed varieties that would be higher yielding, drought tolerant and resistant to pests and diseases, and so help secure and improve local cowpea production in sub-Saharan African countries.

Photo: IITA

A trader selling cowpea at Bodija market, Ibadan, Nigeria.

Cowpea production – almost all of it comes from Africa

A type of legume originating in West Africa, cowpeas are also known as niébé in francophone Africa and as black-eyed peas in the USA.  They are well adapted to drier, warmer regions and grow well in poor soils. In Africa, they are mostly grown in the hot, drought-prone savannas and very arid sub-Saharan regions, often together with pearl millet and sorghum.

Nutritionally, cowpeas are a major source of dietary protein in many developing countries. Young leaves, unripe pods and peas are used as vegetables, and the mature grain is processed for various snacks and main meal dishes. As a cash crop, both for grain and animal fodder, cowpea is highly valued in sub-Saharan Africa.

Worldwide, an estimated 14.5 million hectares of land is planted with cowpea each year. Global production of dried cowpeas in 2010 was 5.5 million tonnes, 94 percent of which was grown in Africa.

“In Senegal, cowpeas cover more than 200,000 hectares,” says Ndiaga Cissé, cowpea breeder at L’institut sénégalais de recherches agricoles (ISRA; Senegalese Agricultural Research Institute). “This makes it the second most grown legume in Senegal, after groundnuts.”

In 2011, Senegal experienced its third drought within a decade. Low and erratic rainfall led to poor harvests in 2011 and 2012: yields of cereal crops (wheat, barley and maize) fell by 36 percent compared to 2010. Consequently, the hungry period in 2012 started three months earlier than usual, making gap-fillers like cowpea even more important. In fact, cereal production in sub-Saharan African countries has not seen substantial growth over the last two decades – total area, yield and production grew by only 4.3 percent, 1.5 percent and 5.8 percent, respectively.

Climate change is expected to further compound this situation across sub-Saharan Africa. Droughts are forecast to occur more frequently, weakening plants and making them more vulnerable to pests and diseases.

“Improved varieties of cowpeas are urgently needed to narrow the gap between actual and potential yields,” says Ndiaga. “They will not only provide security to farmers in the face of climate change, but will also help with food security and overall livelihoods.”

Photo: IITA

Farmers in Northern Nigeria transport their cowpea harvest.

Mapping the cowpea genome

For over 30 years, Phil Roberts, a professor in the Department of Nematology at the University of California, Riverside (UCR), has been breeding new varieties of cowpea. “UCR has a long history of research in cowpea breeding that goes back to the mid-seventies,” explains Phil. “One of the reasons we were commissioned by GCP in 2007 was to use our experience, particularly in using molecular breeding, to help African cowpea-breeding programmes produce higher yielding cowpeas.”

For seven years, Phil and his team at UCR coordinated the cowpea component of the Tropical Legumes I (TLI) project led by GCP (see box below).  The objective of this work was to advance cowpea breeding by applying modern, molecular breeding techniques, tools and knowledge to develop lines and varieties with drought tolerance and resistance to pests and diseases in the sub-Saharan African countries Burkina Faso, Mozambique, Nigeria and Senegal.

The molecular breeding technology that UCR uses for cowpeas is based on finding genes that help cowpea plants tolerate insects and diseases, identifying markers that can indicate the presence of known genes, and using these to incorporate valuable genes into higher yielding varieties.

“Using molecular breeding techniques is a lot easier and quicker, and certainly less hit-or-miss, than conventional breeding techniques,” says Phil. “We can shorten the time needed to breed better adapted cowpea varieties preferred by farmers and markets.”

Phil explains that the first priority of the project was to map the cowpea genome.

“The map helps us locate the genes that play a role in expressing key traits such as drought tolerance, disease resistance or pest resistance,” says Phil. “Once we know where these genes are, we can use molecular marker tools to identify and help select for the traits. This is a lot quicker than growing the plant and observing if the trait is present or not.”

To use an analogy, think of the plant’s genome as a story: its words are the plant’s genes, and a molecular marker works as a text highlighter. Molecular markers are not precise enough to highlight specific words (genes), but they can highlight sentences (genomic regions) that contain these words (genes), making it easier and quicker to identify which plants have them. Traditionally, breeders have needed to grow plants to maturity under appropriately challenging conditions to see which ones are likely to have useful traits, but by using markers to flag valuable genes they are able to largely skip this step, and test large amounts of material to choose the best parents for their crosses, then check which of the progeny have inherited the gene or genes.

Photo: IITA

Diversity of cowpea seed.

Breeding new varieties faster, using modern techniques

Photo: ICRISAT

A farmer pleased with her cowpea plants.

The main focus of the cowpea component in TLI was to optimise marker-assisted recurrent selection (MARS) and marker-assisted backcrossing (MABC) breeding techniques for sub-Saharan African environments and relevant traits.

MARS identifies regions of the genome that control important traits. In the case of cowpeas, these include drought tolerance and insect resistance. It uses molecular markers to explore more combinations in the plant populations, thus increasing breeding efficiency.

MABC is the simplest form of marker-assisted breeding, in which the goal is to incorporate a major gene from an agronomically inferior source (the donor parent) into an elite cultivar or breeding line (the recurrent parent). Major genes by themselves have a significant effect; it’s therefore easier to find a major gene associated with a desired trait, than having to find and clone several minor genes. The aim is to produce a line made up almost entirely of the recurrent parent genotype, with only the selected major gene from the donor parent.

Using the genome map and molecular markers, the UCR team identified 30 cowpea lines with drought tolerance and pest resistance from 5,000 varieties in its collection, providing the raw material for marker-assisted breeding. “Once we knew which lines had the drought-tolerance and pest-resistance genes we were looking for, we crossed them with high-yielding lines to develop 20 advanced cowpea lines, which our African partners field tested,” says Phil.

The lines underwent final field tests in 2014, and the best-yielding drought-tolerant lines will be used locally in Burkina Faso, Mozambique and Senegal to develop new higher yielding varieties that will be available to growers by 2016.

“While we are still some time off from releasing these varieties, we already feel we are two or three years ahead of where we would be if we were doing things using only conventional breeding methods,” says Ndiaga.

Photo: IITA

A parasitic Striga plant, in a cowpea experimental plot.

The genome map and molecular markers have helped cowpea breeders like Ousmane Boukar, cowpea breeder and Kano Station Representative with the International Institute of Tropical Agriculture (IITA), headquartered in Nigeria, to locate the genes in cowpeas that play a role in expressing desirable traits.

Ousmane, who was GCP’s cowpea Product Delivery Coordinator, says, “We have used this technology to develop advanced breeding lines that are producing higher yields in drier conditions and displaying resistance to several pests and diseases like thrips and Striga. We expect these lines to be available to plant breeders by the end of 2015.

“TLI has had a huge impact in Africa in terms of developing capacity to carry out marker-assisted breeding,” he says. “This form of breeding helps us to breed new varieties in three to five years instead of seven to ten years.”

The Tropical Legumes I project (TLI) was initiated by GCP in 2007 and subsequently incorporated into the Programme’s Legumes Research Initiative (RI). The goal of the RI was to improve the productivity of four legumes – beans, chickpeas, cowpeas and groundnuts – that are important in food security and poverty reduction in developing countries, by providing solutions to overcome drought, poor soils, pests and diseases. TLI was led by GCP and focussed on Africa. Work on cowpea within TLI was coordinated by the University of California, Riverside in the USA. Target-country partners were Institut de l’Environnement et de Recherches Agricoles (INERA) in Burkina Faso, Universidade Eduardo Mondlane in Mozambique and Institut Sénégalais de Recherches Agricoles (ISRA; Senegalese Agricultural Research Institute) in Senegal. Other partners were the International Institute of Tropical Agriculture (IITA) and USA’s Feed the Future Innovation Labs for Collaborative Research on Grain Legumes and for Climate-Resilient Cowpea. Tropical Legumes II (TLII) was a sister project to TLI, led by the International Crops Research Institute for the Semi-Arid Tropics (ICRISAT) on behalf of IITA and the International Centre for Tropical Agriculture (CIAT). It focussed on large-scale breeding, seed multiplication and distribution primarily in sub-Saharan Africa and South Asia, thus applying the ‘upstream’ research results from TLI and translating them into breeding materials for the ultimate benefit of resource-poor farmers. Many partners in TLI also worked on projects in TLII.

Burkina Faso – evaluating new lines to improve the country’s economy

Cowpea is an important crop for the people of Burkina Faso. Over 10 million farmers produce on average 800,000 tonnes of cowpeas each year, making the country the third largest producer in the world, behind neighbours Nigeria and Niger.

Much of Burkina Faso’s cowpea crop is consumed domestically, but the government sees potential in increasing productivity for export to Côte d’Ivoire and Ghana in the south. This new venture would improve the country’s gross domestic product (GDP), which is the third lowest in the world.

“The government is very interested in our research to improve cowpea yields and secure them against drought and disease,” says Issa Drabo, lead cowpea breeder with the Institut de l’Environnement et de Recherches Agricoles (INERA) in Burkina Faso.

“We’ve been working closely with UCR to evaluate advanced breeding lines that we can use in our own breeding programme. So far we have several promising lines, some of which breeders are using to create varieties for release to farmers – some as early as this year.”

Photo: IITA

Farmers in Burkina Faso discuss cowpea varieties during participatory varietal selection activities.

Outsourcing the molecular work

Issa says his team has mainly been using conventional breeding techniques and outsourcing the molecular breeding work to the UK and USA. “We send leaf samples to the UK to be genotyped by a private company [LGC Genomics], who then forward the data to UCR, who analyse it and tell us which plants contain the desired genes and would be suitable for crossing.”

The whole process takes four to six weeks, from taking the samples to making a decision on which plants to cross.

“This system works well for countries that don’t have the capacity or know-how to do the molecular work,” says Darshna Vyas, a plant genetics specialist with LGC Genomics. “Genotyping has advanced to a point where even larger labs around the world choose to outsource their genotyping work, as it is cheaper and quicker than if they were to equip their lab and do it themselves. We do hundreds of thousands of genotyping samples a day – day in, day out. It’s our business.”

Darshna says LGC Genomics have also developed plant kits, as a result of working more with GCP partners from developing countries. “We would receive plant tissue that was not properly packaged and had become mouldy on the journey. The plant kits help researchers package their tissue correctly. The genotyping data you get from undamaged tissue compared to damaged tissue is a thousand times better.”

Getting the genotyping expertise on the ground

Photo: IITA

A trader bagging cowpeas at Bodija market, Ibadan, Nigeria.

To reduce their African partners’ reliance on UCR, researchers from the university, including Phil, have been training young plant breeders and PhD students from collaborating institutes. Independent of the cowpea project, they have also been joining GCP’s Integrated Breeding Platform (IBP) training events in Africa to help breeders understand the new technologies.

“All this capacity building we do really gets at the issue of leaving expertise on the ground when the project ends,” says Phil. “If these breeders don’t have the expertise to use the modern breeding technologies, then we won’t make much progress.”

GCP Capacity Building Theme Leader and TLI Project Manager Ndeye Ndack Diop has been impressed by UCR’s enthusiasm to build capacity in its partner countries. “Capacity building is a core objective for GCP and the TLI project,” says Ndeye Ndack. “While it is built into almost all GCP projects, UCR have gone over and above what was expected of them and contributed towards building capacity not only among its partner institutions, but in many other African national breeding institutes as well.”

Issa Drabo reports that in 2014 two of his young researchers from Burkina Faso completed their training in GCP’s Integrated Breeding Multiyear Course, conducted by UCR and the IBP team.

One of Issa’s researchers at INERA, Jean-Baptiste de la Salle Tignegré, says the course helped him understand more about the background genetics, statistical analysis and data management involved in the process of molecular breeding. “Because of the course, we are now able to analyse the genotype data from LGC,” he says.

Mozambique – insects and drought are the problem

In 2010, the Universidade Eduardo Mondlane (UEM) joined the cowpea component of TLI, three years after the project started. “We were a little late to the party because we were busy setting up Mozambique’s first cowpea breeding programme, which only began in 2008,” recalls Rogerio Chiulele, a lecturer at the university’s Faculty of Agronomy and Forestry Engineering and lead scientist for cowpea research in Mozambique for TLI.

That year (2008), UEM received a GCP Capacity building à la carte grant to establish a cowpea-breeding programme for addressing some of the constraints limiting cowpea production and productivity, particularly drought, pests and diseases.

As in Burkina Faso and Senegal, in Mozambique cowpeas are an important source of food, for both protein and profit, particularly for the poor. Cowpeas rank as the fourth most cultivated crop in Mozambique, accounting for about nine percent of the total cultivated area, or an estimated four million hectares of smallholder farms.

Photo: IITA

Cowpea plants infested by aphids.

Rogerio says that farmers in his country, just as in other parts of Africa, struggle to reach their full yield potential because of climate, pests and diseases. “Several insect pests – such as aphids, flower thrips, nematodes and pod-sucking pests – can substantially reduce cowpea yield and productivity in Mozambique,” he says.

“Cowpea aphids can cause problems at any time in the growing season, but are most damaging during dry weather when they infest seedlings that are stressed from lack of water. In wetter parts of the country, flower thrips – which feed on floral buds – are the most damaging insect pest.” These insects are also major pests in Burkina Faso and Senegal, along with hairy caterpillar (Amsacta moloneyi), which can completely destroy swaths of cowpea seedlings.

Rogerio says breeding for insect resistance and drought tolerance, using marker-assisted techniques, improves breeders’ chances of increased cowpea productivity. “Productivity is key to increasing rural incomes, and new resources can then be invested in other activities that help boost total family income,” says Rogerio. “These new breeding techniques will help us achieve this quicker.”

Three high-yielding varieties to hit the Mozambique market in 2015

Photo: IITA

Mature cowpea pods ready for harvesting.

Since 2010, Rogerio’s team have quickly caught up to Burkina Faso and Senegal and plan to release three higher yielding new lines with drought tolerance in 2015. One of these lines, CB46, is based on a local cowpea variety crossed with a UCR-sourced American black-eyed pea variety that displays drought tolerance, which potentially has huge market appeal.

“Local varieties fetch, on average, half a US dollar per kilogram, compared to black-eyed pea varieties, whose price is in the region of four to five US dollars,” says Rogerio. “Obviously this is beneficial to the growers, but the benefits for consumers are just as appealing. The peas are better quality and tastier, and they take half as long to cook compared to local varieties.”

All these extra qualities are important to consider in any breeding programme and are a key objective of the Tropical Legume II (TLII) project (see box above). TLII activities, led by ICRISAT, seek to apply products from TLI to make an impact among farmers.

“TLII focuses on translating research outputs from TLI into tangible products, including new varieties,” says Ousmane Boukar, who works closely with Ndiaga, Issa and Rogerio in TLI and TLII.

Building a community of breeders to sustain success

Photo: C Peacock/IITA

Cowpea flower with developing pods.

Part of Ousmane’s GCP role as Product Delivery Coordinator for cowpeas was to lead a network of African cowpea and soybean breeders, and he champions the need for breeders to share information and materials as well as collaborating in other ways so as to sustain their breeding programmes post-GCP.

“To sustain integrated breeding practices post-2014, GCP has established Communities of Practice (CoP) that are discipline- and commodity-oriented,” says Ndeye Ndack. “The ultimate goal is to provide a platform for community problem solving, idea generation and information sharing.”

Ousmane says the core of this community was already alive and well before the CoP. “Ndiaga, Issa and I have over 80 years combined experience working on cowpea. We have continually crossed paths and have even been working together on other non-GCP projects over the past seven years.”

One such project the trio worked together on was to release a new drought-tolerant cowpea breeding line, IT97K-499-35, in Nigeria. “The performance of this variety impressed farmers in Mali, who named it jiffigui, which means ‘hope’,” says Ousmane. “We shared these new lines with our partners in Mali and Niger so they could conduct adaptation trials in their own countries.”

For young breeders like Rogerio, the CoP has provided an opportunity to meet and learn from these older partners. “I’ve really enjoyed our annual project meetings and feeling more a part of the world of cowpea breeding, particularly since we in Mozambique are isolated geographically from larger cowpea-producing countries in West Africa.”

For Phil Roberts, instances where more-established researchers mentor younger researchers in different countries give him hope that all the work UCR has done to install new breeding techniques will pay off. “Young researchers represent the future. If they can establish a foothold in breeding programmes in their national programmes, they can make an impact. Beyond having the know-how, it is vital to have the support of the national programme to develop modern breeding effort in cowpea – or any crop.”

Setting up breeders for the next 20 years

Photo: IITA

Farmer harvesting mature cowpea pods.

In Senegal, Ndiaga is hopeful that the work that the GCP project has accomplished has set up cowpea breeders in his country and others for the next 20 years.

“Both GCP’s and UCR’s commitment to build capacity in developing countries like Senegal cannot be valued less than the new higher yielding, drought-tolerant varieties that we are breeding,” says Ndiaga. “They have provided us with the tools and skills now to continue this research well into the future.

“We are close to releasing several new drought-tolerant and pest- and disease-resistant lines, which is our ultimate goal towards securing Senegal’s food and helping minimise the impact of the hungry period.”

More links

Jun 052015
 
Photo: Bill & Melinda Gates Foundation

Farmer Maria Mtele holds recently harvested orange-fleshed sweetpotatoes in a field in Mwasonge, Tanzania.

Sweetpotato has a long history as a lifesaver. The Japanese used it when typhoons demolished their rice fields. It kept millions from starvation in famine-plagued China in the early 1960s and came to the rescue in Uganda in the 1990s, when a virus ravaged the cassava crop.

In sub-Saharan Africa, sweetpotato is proving crucial in the fight against blindness, disease and premature death among children under five. And, as agriculture becomes more market-oriented across the continent, sweetpotato has some significant advantages: it requires fewer inputs and less labour than other crops such as maize, tolerates marginal growing areas and can mature within four months.

On these fertile grounds, researchers across the globe are not underestimating the importance of sweetpotato as a staple crop.

“Yields achieved by resource-poor farmers in sub-Saharan Africa are typically low,” says Roland Schafleitner of the International Potato Center (CIP), based in Peru.

“Improved and well-adapted sweetpotato varieties with increased tolerance to drought, pests and diseases will have a positive impact on food and income security in sub-Saharan Africa and can significantly contribute to increasing productivity,” he says.

Roland was Principal Investigator of two research projects funded by the CGIAR Generation Challenge Programme (GCP), which developed genetic and genomic resources for breeding improved sweetpotato.

At the outset of the work, Roland says: “Breeding efforts were limited by the crop’s genetic complexity and the lack of information available about its genetic resources.

“It was clear that if we could develop genetic tools and make concerted efforts towards understanding the gene pool of sweetpotato, the breeding potential of the crop would improve.”

Photo: Bill & Melinda Gates Foundation

Farmer Mwanaidi Rhamdani at work in an orange-fleshed sweetpotato field in Mwasonge, Tanzania.

Sub-Saharan Africans getting their vitamin A from sweetpotato

Photo: CIP

Sweetpotato diversity.

Malnutrition does not always mean a simple lack of calories; research suggests that nutrient shortfalls are an even bigger killer. Vitamin A deficiency is a leading cause of blindness, infectious disease and premature death among children under five and pregnant women in sub-Saharan Africa and Asia.

Sweetpotato comes in a wide range of colours. Varieties with dark orange flesh are naturally very rich in the pigment beta-carotene, which the body converts into vitamin A. However, the sweetpotatoes traditionally grown in Africa are pale-fleshed and low in beta-carotene. African consumers were not used to eating colourful sweetpotato – and these orange-fleshed varieties were in any case not well adapted African growing conditions.

Recent years have therefore seen a collaborative effort by researchers across the world to breed orange-fleshed sweetpotato varieties fortified with high levels of beta-carotene, and even enriched with other nutrients, that have also been crossed with local varieties and so are adapted to local conditions and tastes. A crucial part of these efforts has also been to create public awareness and encourage people to grow, eat and buy these new varieties.

Photo: HarvestPlus

Two cheeky young chappies from Mozambique enjoy the sweet taste of orange-fleshed sweetpotato rich in beta-carotene, or pro-vitamin A.

All of this adds to the growing momentum behind sweetpotato. The growing awareness of sweetpotato’s potential nutritional benefits for the poor and food insecure, as well as its value for subsistence farmers as a reliable crop that withstands drought and requires minimal inputs, mean that it is growing in significance.

Photo: HarvestPlus

Orange-fleshed sweetpotato can be used to make a variety of tasty products from doughnuts to chapati.

More than 95% of the world’s sweetpotato crop is grown in developing countries, where it is the fifth most important staple food crop. It is particularly important in many African countries: Madagascar in Southern Africa; Nigeria in West Africa; and those surrounding the Great Lakes in East and Central Africa – Uganda, Malawi, Angola and Mozambique.

According to 2013 figures from the Food and Agriculture Organization of the United Nations, 3.6 million hectares of sweetpotato were harvested in Africa. While the average global yield of sweetpotato per hectare was 14.8 tonnes, across all East African countries in 2013 it was only half this, at 7.1 tonnes per hectare. In West African nations the average yield was even worse, at 3.7 tonnes per hectare.

Farmers are unable to make the most of their crops because the varieties available to them, including traditional varieties (or landraces) have low resistance to viral diseases and insect pests, and poor tolerance to drought. It is therefore crucial that when developing new varieties breeders are able to efficiently incorporate pest and disease resistance and drought tolerance traits.

Sweetpotato, in spite of its name, is only distantly related to the potato. Unlike the potato – which is a tuber, or thickened stem – the sweetpotato is a root. Sweetpotato is not related to the yam either, despite the physical similarity between the two. Sweetpotato can grow at altitudes ranging from sea level to 2,500 metres. It requires fewer inputs and less labour than other crops such as maize, and, in contrast to the potato, it can tolerate heat.

New DNA markers identified for sweetpotato disease

The sweetpotato virus disease (SPVD) is the most serious disease affecting sweetpotato in sub-Saharan Africa. It often causes serious yield losses of up to 80–90 percent.

The disease is the result of joint infection by two viruses: the sweetpotato feathery mottle virus and the sweetpotato chlorotic stunt virus. Of the two, the stunt virus is the more problematic.

Wolfgang Grüneberg, also from CIP, says that, in the years 2006–2008, 52 new DNA markers were developed as part of GCP-funded research to improve marker-assisted selection for resistance to the disease.

“The results,” says Wolfgang, Principal Investigator for the research, “looked promising for developing a large number of orange-fleshed sweetpotatoes with resistance to SPVD.”

Immediately following the development of the markers, two varieties of sweetpotato were developed using a cloned gene, Resistan, known to confer resistance to the virus. The first variety was used to improve an SPVD test system so that the disease could be diagnosed earlier if a crop was affected. The second variety underwent field tests in regions in Uganda that were highly affected by the disease.

Photo: HarvestPlus

Sweetpotato vines and roots.

Mobilising the genetic diversity of sweetpotato for breeding

The goals of the GCP-supported work were to develop a diverse genetic resource base for sweetpotato and stimulate the use of new tools in ongoing breeding programmes.

To help transfer this work from high-end laboratories to resource-poor research labs in developing countries, GCP promoted collaboration across institutions and borders. Researchers from Brazil, Mozambique, Uganda and Uruguay worked together on sweetpotato genetic research projects.

As Roland explains, the basic first steps needed to begin to ‘mobilise’ the genetic diversity of sweetpotato were developing a reference set of varieties and improving genomics tools to work with polyploid crops, i.e. those possessing multiple sets of chromosomes, such as sweetpotato.

GCP-supported researchers in Peru and sub-Saharan Africa defined a reference set of 472 varieties of sweetpotato, carefully selected and honed to represent both the diversity of the crop and its most important agronomical and nutritional traits.

“Based on a reference set, genetic markers can be developed that are associated with important characteristics of the crop and can help breeders to select favourable genotypes,” says Roland.

The gene sequences developed during the Programme are now available as a Sweetpotato Gene Index.

“Based on these sequences,” says Roland, “molecular markers have been designed that can help breeders and gene-bank curators to assess the genetic diversity of their accessions and to perform genetic mapping studies.

“Today, techniques that yield a much larger number of markers for genetic studies and selection are accessible for sweetpotato,” he says.

Photo: Bill & Melinda Gates Foundation

Mwanaidi Rhamdani (left) works with Maria Mtele in an orange-fleshed sweetpotato field in rural Tanzania.

The genetic lifelines reach Africa

Sweetpotato is one of the most important staple crops in Mozambique, ranking in third position after cassava and maize. The areas harvested in Mozambique in 2013 were 1.7 million hectares of maize, 780,000 hectares of cassava and 120,000 hectares of sweetpotato.

Photo: CIP

A child eats cooked orange-fleshed sweetpotato in Uganda.

GCP funded breeders in Mozambique and Uganda to learn how to identify genetic markers that would prove useful for future sweetpotato breeding.

“Our African partners visited us at CIP and helped us complete the work on identifying markers,” recalls Roland. “This provided the opportunity for direct ‘technology transfer’ to breeders in the target region.”

The collaboration had, for the first time, created a critical amount of genetic and genomics resources for sweetpotato. The resulting Sweetpotato Gene Index and the new markers were published in a peer-reviewed journal, BMC Genomics (2010) 11:604.

The new genetic resources are in use at CIP in Peru and in breeding programmes in Burkina Faso, Mozambique, Uganda, Uruguay and the USA for the assessment of the genetic diversity of germplasm collections.

“The markers have been used for diversity analysis, especially at the CIP gene bank, and also in Africa,” says Roland, who says the markers will help future research.

“Such analysis guides germplasm conservation decisions, and diversity studies are a great tool to develop core collections and composite genotype sets – subsets of the whole collection – which allow for more practical screening for specific traits than large collections.”

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Photo: P Casier/CGIAR

Kenyan farmer Emily Marigu with her sweetpotatoes.

Jun 022015
 
Photo: S Edmeades/IFPRI

A farmer transports bananas to market by bicycle in Uganda.

At whatever time of the day or night you are reading this, somewhere in the world there are sure to be farmers trekking many kilometres to take their bananas to local markets. These small-scale farmers produce almost 90 percent of the world’s bananas, and make up a significant portion of the 400 million people around the globe’s tropical girdle – Africa, Asia and Latin America – who rely on bananas for food and a source of income.

Bananas are often called the world’s most popular fruit, and global production in 2012 was almost 140 million tonnes. India is the largest producer, while South and Central American farmers supply the most to international supermarket shelves, exporting 80 percent of their bananas.

The importance of the banana as a food crop in tropical areas cannot be underestimated. More than a simple snack, plantain-type bananas in particular are a key component in savoury dishes. In Central and East African countries – like Cameroon, Gabon, Rwanda and Uganda – one person will eat an average of between 100 kg and 250 kg of banana each year. That equates to somewhere between 800 and 2000 average-sized bananas. In those four countries, bananas account for up to a quarter of people’s daily calorie intake.

Photo:  A Vezina/Bioversity International

A stallholder offers bananas for sale at a fruit market in Nairobi, Kenya.

Banana’s asexuality inhibits its resilience

Photo: G Stansbury/IFPRI

Bananas growing in Rwanda.

Banana propagates though asexual reproduction. This means that all the bananas of each variety are genetically identical, or nearly so, and therefore susceptible to the same diseases. Indeed, the world has already lost almost its entire banana crop once: before the 1950s, the Gros Michel cultivar dominated banana exports, but it was gradually wiped out in most regions by Panama disease, caused by the fungus Fusarium oxysporum. Furthermore, with reproduction being asexual, it is difficult to develop new, resistant varieties through conventional breeding.

At the turn of the twenty-first century, pests and diseases were once again becoming a real threat to global banana production. Little genetic research had been done on the fruit, and only a small portion of its genes had been used in breeding new varieties in its 7,000-year history as a cultivated crop.

“Several research groups had developed genetic markers for bananas [‘flags’ on the genome that can be linked to physical traits], but there was no coordination and only sketchy germplasm studies,” recalls Jean Christophe Glaszmann from CIRAD (Centre de coopération internationale en recherche agronomique pour le développement; Agricultural Research for Development) in France.

Photo: N Palmer/CIAT.

A plantain farmer walks through a plantation in Quindió, Colombia.

“It was not a priority,” says Jean Christophe, who was Subprogramme Leader for Genetic Diversity for the CGIAR Generation Challenge Programme (GCP), an international initiative established in 2004 to encourage the use of genetic diversity and advanced plant science to improve crops.

But between 2004 and 2012, under GCP, a wealth of research work was undertaken that culminated in the complete genetic sequencing of banana. It was a long process, says Jean Christophe, but the GCP-funded work on banana made a significant contribution to important results.

The extensive data on the genetics of banana are now available to scientists worldwide, who can use it to delve deeper into banana’s genes to breed varieties that can sustain the poorer populations in developing countries.

Once finally sequenced, the banana genome was published in one of the most prestigious scientific journals, Nature, in July 2012: “The reference Musa [banana and plantains] genome sequence represents a major advance in the quest to unravel the complex genetics of this vital crop, whose breeding is particularly challenging. Having access to the entire Musa gene repertoire is a key to identifying genes responsible for important agronomic characters, such as fruit quality and pest resistance.”

Filling and full of fuel, and with the major advantage that it fruits year-round, the banana is vital to food security in the tropics. Bananas are potassium-rich and supply people in developing countries with a major source of carbohydrates. They also provide vitamin A, niacin, vitamin B6, thiamine, riboflavin and folic acid.

Passionate people pooled for the work

Photo: UN Women Asia & the Pacific

A banana seller in Hanoi, Vietnam.

Plans to sequence the banana genome started taking shape in 2001 at Bioversity International (a CGIAR centre), where a group of scientists formed the Global Musa Genomics Consortium. At that time, the only plant whose genome had been sequenced was Arabidopsis thaliana (a small flowering plant related to cabbage and mustard, used as a model organism in plant science), with rice close behind.

CGIAR established GCP in 2004 “to tap into the rich genetic diversity of crops via a global network of partnerships and breeding programmes,” according to Hei Leung, who was instrumental to GCP’s foundation and a Subprogramme Leader for Comparative Genomics. (During its first phase GCP was organised by Subprogramme; these were later replaced by Research Themes and Research Initiatives.)

Hei acknowledges that banana was ‘somewhat on the fringe’ of GCP’s main focus on improving drought tolerance in crops. However, he says, it was still relevant for GCP to support the emergence of improved genetics for banana.

The work we did in genetic diversity is about future generations. We wanted a programme that is pro-poor, meaning that the majority of the people in the world are depending on [the crop].

Photo: Adebayo/IITA

A typical banana and plantain market at Ikire in Osun State, Nigeria.

“Drought tolerance is a good candidate because drought affects a lot of poor areas, but you really cannot just take one trait as pro-poor. We had a highly motivated group of researchers willing to devote their efforts to Musa,” says Hei.

“Nicolas Roux at Bioversity International was a passionate advocate for the partnership,” notes Hei. “The GCP community offered a framework for novel interactions among banana-related actors and players working on other crops, such as rice.”

Nicolas concurs on the potential for a little banana research to have great value: “Even though banana is among the most important basic food crops for 400 million people, and 100 million tonnes are grown annually on over 10 million hectares in 120 countries, it’s still under-researched and underfunded.”

The resultant research team was led by Japan’s National Institute of Agrobiological Sciences, which had vast experience in rice genome sequencing.

“So, living up to its name as a Challenge Programme, GCP decided to take the gamble on banana genomics and help it fly,” says Hei.

To advance genetics, you first need the intelligence

Photo: IITA

Banana bunches on an experimental plot at IITA.

Three global research agencies were charged with working together to develop a reference set for banana: Bioversity International, CIRAD, and the International Institute of Tropical Agriculture (IITA).

Creating a reference set – a careful, tactical selection representing the genetic diversity of a crop – is an invaluable first step in enabling scientists to work together to develop more ‘intelligent’ genetic data.

“Initially, we put together a community of institutions that have collections [of banana germplasm],” explains Jean Christophe. “And then we put together these initial materials that we sample in order to develop representative subsamples – this is called a ‘composite’ set because it comes from different institutions.

“Then we genotype this composite collection, and the genotyping allows us to understand how all this [genetic material] is structured. Based on how it is structured, we can re sample a smaller representation – this is what becomes a reference set.”

So, in the case of crops with an extensive genetic resource base, such as rice, there may be more than 100,000 different plant samples, or accessions, that are reduced to a few thousand. For banana, which has a smaller genetic resource base, a few hundred thousand accessions can be reduced to a few dozen.

“A couple of hundred accessions or fewer become manageable for plant breeders or crop specialists. And we want this to serve as a reference, shared among people, so that everybody works on the same reference material,” says Jean Christophe.

“If you work on the same reference material, you can compile information that is more intelligent – you can have the crop specialist who says ‘this is resistant; this is tolerant; this is susceptible’, and you can also have the biochemist, you can have the physiologist; in the end, you can compile the information.”

“We analysed about 500 accessions and narrowed it down to 50,” says Jean Christophe. This reference collection is currently stored at the University of Leuven in Belgium.

The refined data collected on the banana reference set enabled the researchers to unravel the origin and genealogy of the most important dessert banana: the Cavendish, the cultivar subgroup that dominates banana exports worldwide. Thanks to the early GCP work, they were able to show that Cavendish bananas evolved from three markedly different subspecies.

Photo: C Sokunthea/World Bank

65-year-old Cambodian farmer, Khout Sorn, stands in front of his banana trees in Aphiwat Village, Tipo commune, Cambodia.

Malaysian wild subspecies fully sequenced

During these preliminary years of GCP-supported research on banana, the Programme funded several other smaller projects to consolidate genomic resources available for banana. Scientists developed libraries of artificial chromosomes that can be used in sequencing the DNA of banana, as well as genetic maps, which according to Jean Christophe are essential for improving the quality of the sequence.

These projects contributed to the full genome sequencing of a wild banana from Malaysia’s Pahang province in 2008. The ‘Pahang’ subspecies is one of the Cavendish variety’s three ancestors, and has also been shown to have had a role in the origin of many other banana cultivars, including those that are most important for food and economic security.

“GCP did not fund the sequence [of the Pahang banana], but it funded several things that made it possible to undertake full-scale sequencing,” Jean Christophe says. “It supported the development of particular resources and tools, and this made it possible for researchers to start the full-length sequencing.”

Photo: Asian Development Bank

A farmer at work on a banana plantation, Mindanao, the Philippines.

Breeders now need to set to work

The more that is known about the genes responsible for disease resistance and other desirable traits in banana, the more researchers will be able to help farmers in developing countries to improve their yields.

“The road remains long, but now we have a good understanding of genetic diversity,” says Jean Christophe. “We have done a range of studies aimed at unravelling the genes that could control sterility in the species.

“This is undoubtedly an inspiring challenge towards unlocking the genetic diversity in this crop.

“If we have more money in the future, we are going to sequence others of the subspecies so that we can have the full coverage of the current Cavendish genome. But that was a good start,” says Jean Christophe.

“What we have to do now is to create the right populations [of banana] in the field so that we can separate out the characteristics we want to breed for.”

The new intelligence on banana genetics has given breeders the material they need that will ultimately help 400 million people in the tropics sustain food supplies and livelihoods.

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Photo: N Palmer/CIAT

Bananas on the way to market in Kenya.

Jun 012015
 

Crop science and collaboration help African farmers feed India’s appetite for chickpeas

Photo: ICRISAT

Indian chickpea farmer with her harvest.

India loves chickpeas. With its largely vegetarian population, it has long been the world’s biggest producer and consumer of the nutritious legume. In recent years, however, India’s appetite for chickpea has outstripped production, and the country is also now the world’s biggest importer. With a ready market and new drought-tolerant varieties of chickpea, millions of smallholder African farmers are ready to make up India’s shortfall, improving livelihoods along the way and ensuring food security for some of the world’s most resource-poor countries.

GCP achieved real impacts in chickpea by catalysing and facilitating the deployment of advanced crop science, particularly molecular breeding, in the development of drought-tolerant varieties for both Africa and Asia. Over the course of its research, it also contributed to major advances in chickpea science and genomic knowledge.

Although India boasts the world’s biggest total chickpea harvest, productivity has been low in recent years with yields of less than one tonne per hectare, largely due to drought in the south of the country where much chickpea is grown. The country is relying increasingly on exports from producers in sub-Saharan Africa to supplement its domestic supply.

Drought has been hindering chickpea yields in Africa too, however, and this is a major concern not only for Africa but also for India. Ethiopia and Kenya are Africa’s largest chickpea producers, and both countries have been producing chickpea for export. However, their productivity has been limited, mainly because of heat stress and moisture loss, as well as by a lack of access to basic infrastructure and resources.

Indeed, drought has been the main constraint to chickpea productivity worldwide, and in countries such as Ethiopia and Kenya this is often made worse by crop disease, poor soil quality and limited farmer resources. While total global production of chickpea is around 8.6 million tonnes per year, drought causes losses of around 3.7 million tonnes worldwide.

A decade ago, chickpea researchers, supported by the CGIAR Generation Challenge Programme (GCP), started to consider the potential for developing new drought-tolerant varieties that could help boost the world’s production.

They posed this question: If struggling African farmers were armed with adequate resources, could they make up India’s shortfall by growing improved chickpea varieties for export? Empowering farmers to stimulate and sustain their own food production, it was proposed, would not only offer food security to millions of farmers, but could ultimately secure future chickpea exports to India.

Photo: S Sridharan/ ICRISAT

An Ethiopian farmer harvests her chickpea crop.

In 2007, GCP kicked off a plan for a multiphased, multithemed Tropical Legumes I (TLI) project, which later became part of, and the largest project within, the GCP Legumes Research Initiative (RI; see box below) – the chickpea component of which would involve collaboration between researchers from India, Ethiopia and Kenya. The scope was not only to develop improved, drought-tolerant chickpeas that would thrive in semiarid conditions, but also to ensure that these varieties would be growing in farmers’ fields across Africa and South Asia within a decade.

“We knew our task would not be complete until we had improved varieties in the hands of farmers,” says GCP researcher Paul Kimurto from the Faculty of Agriculture, Egerton University, Kenya.

The success of GCP research in achieving these goals has opened up great opportunities for East African countries such as Ethiopia and Kenya, which are primed and ready to take advantage of a guaranteed chickpea market.

The Tropical Legumes I project (TLI) was initiated by GCP in 2007 and subsequently incorporated into the Programme’s Legumes Research Initiative (RI). The goal of the RI was to improve the productivity of four legumes – beans, chickpeas, cowpeas and groundnuts – that are important in food security and poverty reduction in developing countries, by providing solutions to overcome drought, poor soils, pests and diseases. TLI was led by GCP and focussed on Africa. Work on chickpea within TLI was coordinated by the International Crops Research Institute for the Semi-Arid Tropics (ICRISAT). Target-country partners were the Ethiopian Institute of Agricultural Research (EIAR), Egerton University in Kenya and the Indian Institute of Pulses Research. The National Center for Genome Resources in the USA was also a partner. Tropical Legumes II (TLII) was a sister project to TLI, led by ICRISAT on behalf of the International Institute of Tropical Agriculture (IITA) and the International Center for Tropical Agriculture (CIAT). It focussed on large-scale breeding, seed multiplication and distribution primarily in sub-Saharan Africa and South Asia, thus applying the ‘upstream’ research results from TLI and filtering them downstream into breeding materials for the ultimate benefit of resource-poor farmers. Many partners in TLI also worked on projects in TLII.

How drought affects chickpea

Chickpea is a pretty tough customer overall, being able to withstand and thrive on the most rugged and dry terrains, surviving with no irrigation – only the moisture left deep in the soil at the end of the rainy season.

Yet the legume does have one chink in its armour: if no rain falls at its critical maturing or ripening stage (otherwise known as the grain-filling period), crop yields will be seriously affected. The size and weight of chickpea legumes is determined by how successful this maturing stage is. Any stress, such as drought or disease, that occurs at this time will reduce the crop’s yield dramatically.

In India, this has been a particular problem for the past 40 years or so, as chickpea cropping areas have shifted from the cooler north to the warmer south.

“In the 1960s and 1970s when the agricultural Green Revolution introduced grain crops to northern India, chickpeas began to be replaced there by wheat or rice, and grown more in the south,” says Pooran Gaur from the International Crop Research Institute for the Semi-Arid Tropics (ICRISAT), headquartered in India. Pooran was an Activity Leader for the first phase of TLI and Product Delivery Coordinator for the chickpea component of the Legumes RI.

This shift meant the crop was no longer being grown in cooler, long-season environments, but in warmer, short-season environments where drought and diseases like Fusarium wilt have inhibited productivity.

“We have lost about four or five million hectares of chickpea growing area in northern India in the decades since that time,” says Pooran. “In the central and southern states, however, chickpea area more than doubled to nearly five million hectares.”

Escaping drought in India

“The solution we came up with was to develop varieties that were not only high yielding, but could also mature earlier and therefore have more chance of escaping terminal drought,” Pooran explains.

“Such varieties could also allow cereal farmers to produce a fast-growing crop in between the harvest and planting of their main higher yielding crops,” he says.

New short-duration varieties are expected to play a key role in expanding chickpea area into new niches where the available crop-growing seasons are shorter.

“In southern India now we are already seeing these varieties growing well, and their yield is very high,” says Pooran. “In fact, productivity has increased in the south by about seven to eight times in the last 10–12 years.”

The southern state of Andhra Pradesh, once considered unfavourable for chickpea cultivation, today has the highest chickpea yields (averaging 1.4 tonnes/hectare) in India, producing almost as much chickpea as Australia, Canada, Mexico and Myanmar combined.

Photo: ICRISAT

Indian chickpea farmer with her harvest.

Developing new varieties: Tropical Legumes I in action

GCP-supported drought-tolerance breeding activities in chickpea created hugely valuable breeding materials and tools during the Programme’s decade of existence, focussing not only in India but African partner countries of Ethiopia and Kenya too. A key first step in Phase I of TLI was to create and phenotype – i.e. measure and record the observable characteristics of – a chickpea reference set. This provided the raw information on physical traits needed to make connections between phenotype and genotype, and allowed breeders to identify materials likely to contain drought tolerance genes. This enabled the creation in Phase II of breeding populations with superior genotypes, and so the development of new drought-tolerant prebreeding lines to feed into TLII.

A significant number of markers and other genomic resources were identified and made available during this time, including simple sequence repeats (SSRs), single nucleotide polymorphisms (SNPs) and Diversity Array Technologies (DArT) arrays. The combination of genetic maps with phenotypic information led to the identification of an important ‘hot spot’ region containing quantitative trait loci (QTLs) for several drought-related traits.

Two of the most important molecular-breeding approaches, marker-assisted backcrossing (MABC) and marker-assisted recurrent selection (MARS), were then employed extensively in the selection of breeding materials and introgression of these drought-tolerance QTLs and other desired traits into elite chickpea varieties.

Photo: L Vidyasagar/ ICRISAT

Developing chickpea pods

Markers – DNA sequences with known locations on a chromosome – are like flags on the genetic code. Using them in molecular breeding involves several steps. Scientists must first discover a large number of markers, of which only a small number are likely to be polymorphic, i.e. to have different variants. These are then mapped and compared with phenotypic information, in the hope that just one or two might be associated with a useful trait. When this is the case, breeders can test large quantities of breeding materials to find out which have genes for, say, drought tolerance without having to grow plants to maturity.

The implementation of techniques such as MABC and MARS has become ever more effective over the course of GCP’s work in chickpea, thanks to the emergence and development of increasingly cost-effective types of markers such as SNPs, which can be discovered and explored in large numbers relatively cheaply. The integration of SNPs into chickpea genetic maps significantly accelerated molecular breeding.

The outcome of all these molecular-breeding efforts has been the development and release of locally adapted, drought-tolerant chickpea varieties in each of the target countries – Ethiopia, Kenya and India – where they are already changing lives with their significantly higher yields. Further varieties are in the pipeline and due for imminent release, and it is anticipated that, with partner organisations adopting the use of molecular markers as a routine part of their breeding programmes, many more will be developed over the coming years.

Molecular breeding in TLI was done in conjunction with target-country partners, with at least one cross carried out in each country. ICRISAT also backed up MABC activities with additional crosses. The elite lines that were developed underwent multilocation phenotyping in the three target countries and the best-adapted, most drought-tolerant lines were promoted in TLII.

The project placed heavy emphasis on capacity building for the target-country partners. Efforts were made, for instance, to help researchers and breeders at Egerton University in Kenya and the Ethiopian Institute of Agricultural Research (EIAR) in Ethiopia to undertake molecular breeding activities. At least one PhD and two Master’s students each from Kenya, Ethiopia and India were supported throughout this capacity-building process.

The magic of genetic diversity

One of the important advances in chickpea science supported by GCP, as part of TLI and its mission to develop drought-tolerant chickpea genotypes, was the development of the first ever chickpea multiparent advanced generation intercross (MAGIC) population.

It was created using eight well-adapted and drought-tolerant desi chickpea cultivars and elite lines from different genetic origins and backgrounds, including material from Ethiopia, Kenya, India and Tanzania. These were drawn from the chickpea reference set that GCP had previously developed and phenotyped, allowing an effective strategic selection of parental lines. The population was created by crossing these over several generations in such a way as to maximise the mix of genes in the offspring and ensure varied combinations.

MAGIC populations like these are a valuable genetic resource that makes trait mapping and gene discovery much easier, helping scientists identify useful genes and create varieties with enhanced genetic diversity. They can also be directly used as source material in breeding programmes; already, phenotyping a subset of the chickpea MAGIC population has led to the identification of valuable chickpea breeding lines that had favourable alleles for drought tolerance.

Through links with future molecular-breeding projects, it is expected that the investment in the development of MAGIC populations will benefit both African and South Asian chickpea production. GCP was also involved in developing MAGIC populations for cowpea, rice and sorghum, which were used to combine elite alleles for both simple traits, such as aluminium tolerance in sorghum and submergence tolerance in rice, and complex traits, such as drought or heat tolerance.

Decoding the chickpea genome

Photo: ICRISAT

Chickpea seed

In 2013, GCP scientists, working with other research organisations around the world, announced the successful sequencing of the chickpea genome. This major breakthrough is expected to lead to the development of even more superior varieties that will transform chickpea production in semiarid environments.

A collaboration of 20 international research organisations under the banner of the International Chickpea Genome Sequencing Consortium (ICGSC), led by ICRISAT, identified more than 28,000 genes and several million genetic markers. These are expected to illuminate important genetic traits that may enhance new varieties.

“The value of this new resource for chickpea improvement cannot be overstated,” says Doug Cook from the University of California, Davis (UC Davis), United States. “It will provide the basis for a wide range of studies, from accelerated breeding, to identifying the molecular basis of a range of key agronomic traits, to basic studies of chickpea biology.”

Doug was one of three lead authors on the publication of the chickpea genome, along with Rajeev Varshney of ICRISAT, who was Principal Investigator for the chickpea work in GCP’s Legumes RI, and Jun Wang, Director of the Beijing Genomics Institute (BGI) of China.

“Making the chickpea genome available to the global research community is an important milestone in bringing chickpea improvement into the 21st century, to address the nutritional security of the poor – especially the rural poor in South Asia and Africa,” he says.

Increased food security will mean higher incomes and a better standard of living for farmers across sub-Saharan Africa.

For Pooran Gaur, GCP played the role of catalyst in this revolution in genomic resource development. “GCP got things started; it set the foundation. Now we are in a position to do further molecular breeding in chickpea.”

The chickpea genome-sequencing project was partly funded by GCP. Other collaborators included UC Davis and BGI-Shenzhen, with key involvement of national partners in India, Canada, Spain, Australia, Germany and the Czech Republic.

In September 2014, ICRISAT received a grant from the Indian Government for a three-year project to further develop chickpea genomic resources, by utilising the genome-sequence information to improve chickpea.

 Photo: L Vidyasagar/ICRISAT

Indian women roast fresh green chickpeas for an evening snack in Andhra Pradesh, India.

Chickpea success in Africa: new varieties already changing lives

With high-yielding, drought tolerant chickpea varieties emerging from the research efforts in molecular breeding, GCP’s partners also needed to reach out to farmers. Teaching African farmers about the advantages of growing chickpeas, either as a main crop or a rotation crop between cereals, has brought about a great uptake in chickpea production in recent years.

A key focus during the second phase of TLI, and onward into TLII, was on enhancing the knowledge, skills and resources of local breeders who have direct links to farmers, especially in Ethiopia and Kenya, and so also build the capacity of farmers themselves.

“We’ve held open days where farmers can interact with and learn from breeders,” says Asnake Fikre, Crop Research Director for EIAR and former TLI country coordinator of the chickpea work in Ethiopia.

“Farmers are now enrolled in farmer training schools at agricultural training centres, and there are also farmer participatory trials.

“This has given them the opportunity to participate in varietal selection with breeders, share their own knowledge and have their say in which varieties they prefer and know will give better harvest, in the conditions they know best.”

EIAR has also been helping train farmers to improve their farm practices to boost production and to become seed producers of these high-yielding chickpea varieties.

“Our goal was to have varieties that would go to farmers’ fields and make a clearly discernible difference,” says Asnake. “Now we are starting to make that kind of impact in my country.”

In fields across Ethiopia, the introduction of new, drought-tolerant varieties has already brought a dramatic increase in productivity, with yields doubling in recent years. This has transformed Ethiopia’s chickpea from simple subsistence crop to one of great commercial significance.

“Targeted farmers are now planting up to half their land with chickpea,” Asnake says. “This has not only improved the fertility of their soil but has had direct benefits for their income and diets.”

Varieties like the large-seeded and high-valued kabuli have presented new opportunities for farmers to earn extra income through the export industry, and indeed chickpea exports from eastern Africa have substantially increased since 2001.

Photo: A Paul-Bossuet/ICRISAT

“The high yields of the drought-tolerant and pest-resistant chickpea, and the market value, meant that I am no longer seen as a poor widow but a successful farmer,” says Ethiopian farmer Temegnush Dabi.

“Ultimately, by making wealth out of chickpea and chickpea technologies in this country, people are starting to change their lives,” says Asnake. “They are educating their children to the university level and constructing better houses, even in towns. This will have a massive impact on the next generation.”

A similar success story is unfolding in Kenya, where GCP efforts during TLI led to the release of six new varieties of chickpea in the five years prior to GCP’s close at the end of 2014; more are expected to be ready within the next three years.

While chickpea is a relatively new crop in Kenya it has been steadily gaining popularity, especially in the drylands, which make up over 80 percent of Kenya’s total land surface and support nearly 10 million Kenyans – about 34 percent of the country’s population.

Photo: GCP

Drought tolerance experiments in chickpea at Egerton University, Njoro, Kenya.

“It wasn’t until my university went into close collaboration with ICRISAT during TLII and gained more resources and training options – facilitated by GCP – that chickpea research gained leverage in Kenya,” Paul Kimurto explains. “Through GCP and ICRISAT, we had more opportunities to promote the crop in Kenya. It is still on a small scale here, but it is spreading into more and more areas.”

Kenyan farmers are now discovering the benefits of chickpea as a rotational or ‘relay’ crop, he says, due to its ability to enhance soil fertility. In the highlands where fields are normally left dry and nothing is planted from around November to February, chickpea is a very good option to plant instead of letting fields stay fallow until the next season.

“By fixing nitrogen and adding organic matter to the soil, chickpeas can minimise, even eliminate, the need for costly fertilisers,” says Paul. “This is certainly enough incentive for cereal farmers to switch to pulse crops such as chickpea that can be managed without such costs.”

Households in the drylands have often been faced with hunger due to frequent crop failure of main staples, such as maize and beans, on account of climate change, Paul explains. With access to improved varieties, however, farmers can now produce a fast-growing chickpea crop between the harvest and planting of their main cereals. In the drylands they are now growing chickpeas after wheat and maize harvests during the short rains, when the land would otherwise lie fallow.

“Already, improved chickpeas have increased the food security and nutritional status of more than 27,000 households across the Baringo, Koibatek, Kerio Valley and Bomet areas of Kenya,” Paul says.

It is a trend he hopes will continue right across sub-Saharan Africa in the years to come, attracting more and more resource-poor farmers to grow chickpea.

Chickpea’s promise meeting future challenges

Beyond the end of GCP and the funding it provided, chickpea researchers are hopeful they will be able to continue working directly with farmers in the field, to ensure that their interests and needs are being addressed.

“To sustain integrated breeding practices post-2014, GCP has established Communities of Practice (CoPs) that are discipline- and commodity-oriented,” says Ndeye Ndack Diop, GCP’s Capacity Building Leader and TLI Project Manager. “The ultimate goal of the CoPs is to provide a platform for community problem solving, idea generation and information sharing.”

Ndeye Ndack has been impressed with the way the chickpea community has embraced the CoP concept, noting that Pooran has played an important part in this and the TLI projects. “Pooran was able to bring developing-country partners outside of TLI into the CoP and have them work on TLI-related activities. Being part of the community means they have been able to source breeding material and learn from others. In so doing, we are seeing these partners in Kenya and Ethiopia develop their own germplasm.

“Furthermore, much of this new germplasm has been developed by Master’s and PhD students, which is great for the future of these breeding programmes.”

“GCP played a catalytic role in this regard,” explains Rajeev Varshney. “GCP provided a community environment in ways that very few other organisations can, and in ways that made the best use of resources,” he says. “It brought together people from all kinds of scientific disciplines: from genomics, bioinformatics, biology, molecular biology and so on. Such a pooling of complementary expertise and resources made great achievements possible.”

Photo: A Paul-Bossuet/ ICRISAT

An Ethiopian farmer loads his bounteous chickpea harvest onto his donkey.

For Rajeev, the challenge facing chickpea research beyond GCP’s sunset is whether an adequate framework will be there to continue bringing this kind of community together.

“But that’s what we’re trying to do in the next phase of the Tropical Legumes Project (Tropical Legumes III, or TLIII), which kicks off in 2015,” explains Rajeev, who will be TLIII’s Principal Investigator. TLIII is to be led by ICRISAT.

“We will continue to work with the major partners as we did during GCP, which will involve, first of all, upscaling the activities we are doing now,” he says. “India currently has the capacity, the resources, to do this.”

Rajeev is hopeful that the relatively smaller national partners from Ethiopia and Kenya, and associated partners such as Egerton University, EIAR and maybe others, will have similar opportunities. “We hope they can also start working with their governments, or with agencies like USAID, and be successful at convincing them to fund these projects into the future, as GCP has been doing,” he says.

“The process is like a jigsaw puzzle: we have the borders done, and a good idea of what the picture is and where the rest of the pieces will fit,” he says.

Certainly for Paul Kimurto, the picture is clear for the future of chickpea breeding in Kenya.

“Improvements in chickpea resources cannot end now that new varieties have started entering farmers’ fields,” he says. “We’ve managed to develop a good, solid breeding programme here at Egerton University. The infrastructure is in place, the facilities are here – we are indeed equipped to maintain the life and legacy of GCP well beyond 2015.”

This can only be good news for lovers of the legume in India. With millions of smallholder farmers in Kenya and Ethiopia poised to exploit a ready market for new varieties that will change their families’ lives, chickpea’s potential for ensuring food security across the developing world seems more promising than ever.

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May 292015
 

A little over a decade ago, a PhD student in Brazil was poring over sorghum genes, trying to isolate one that helps plants withstand acidic soils.

Photo: B Nichols/USDA

Sorghum

Scientists at the Brazilian Corporation of Agricultural Research (EMBRAPA) had been researching plants that can grow well in acidic soils since the mid-1970s.

“What we have done within the Generation Challenge Programme,” explains Jurandir Magalhães, now a senior scientist for EMBRAPA, as he reflects back on the past decade, “is speed up maize and sorghum breeding for acidic soil adaptation”.

EMBRAPA partnered with the CGIAR Generation Challenge Programme (GCP) to advance plant genetics so as to breed aluminium-tolerant crops that will improve yields in harsh environments, in turn improving the quality of life for farmers.

Almost 70 percent of Brazil’s arable land is made up of acidic soils. That means the soil has toxic levels of aluminium and low levels of phosphorous – a lethal combination that makes crop production unsustainable. Aluminium toxicity in soil comes close to rivalling drought as a food-security threat in critical tropical food-producing regions. This is because acidic soils reduce root growth and deprive plants of the nutrients and water they need to grow.

Robert Schaffert – EMBRAPA’s longest-serving sorghum breeder – had developed mapping populations for aluminium tolerance in sorghum; these populations were the basis for the work supported by GCP.

During the first four years of the 10-year Programme, Jurandir was able to identify and clone the major aluminium-tolerance gene in sorghum – AltSB – using these mapping populations. The cloned gene has since enabled researchers across Africa and Asia to quickly and efficiently breed improved sorghum and maize plants that can withstand acidic soils.

Jurandir, speaking today about the work to advance sorghum genetic resources, says: “Wherever there are acidic soils with aluminium toxicity and low phosphorous availability, our results should be applicable.”

His story with EMBRAPA is one of many where GCP-supported projects have been instrumental in helping global research centres achieve their goals, which ultimately will help farmers worldwide.

Common objectives

Jurandir is now a research scientist in molecular genetics and genomics at the EMBRAPA Maize & Sorghum research centre. He and colleagues at the centre partnered with scientists in Africa, Asia and the US to identify and clone genes in sorghum, maize and rice that confer resistance or tolerance to stresses such as soil acidity, phosphorus efficiency, drought, pests and diseases.

Photo: R Silva/EMBRAPA

Maize growing in Brazil.

“One important focus of GCP was linking basic research to applied crop breeding,” Jurandir says. “This is also the general orientation of our programme at EMBRAPA. We develop projects and research to produce, adapt and diffuse knowledge and technologies in maize and sorghum production by the efficient and rational use of natural resources.

“GCP provided both financial support and a rich scientific community that were useful to help us attain our common objectives.”

EMBRAPA’s work on cloning the AltSB gene would prove to be one of the first steps in GCP’s foundation sorghum and maize projects, both of which sought to provide farmers in the developing world with crops that will not only survive but thrive in the acidic soils where aluminium toxicity reduces crop production.

Leon Kochian of Cornell University in the US was Jurandir’s supervisor at the time when they applied for GCP funding. Leon was a Principal Investigator for various GCP research projects, researching how to improve grain yields of crops grown in acidic soils.

“The breeders are so important,” says Leon about the importance of supporting institutes such as EMBRAPA to advance plant genetics. “Ultimately, they are the cliché of ‘the rubber hits the road’. They’re the ones who translate what we’re trying to figure out into the actual crop improvements. That’s really what it’s all about.”

“That’s why EMBRAPA is a unique institution. Their mission is to get improved seed out, new germplasm out, for the farmers. They have the researchers in sorghum and maize breeding [Robert Schaffert and Sidney Parentoni] and molecular biology [Jurandir Magalhães and Claudia Guimarães].”

Photo: CIFOR

Maize farmers in Brazil.

Great minds think alike

Jurandir’s EMBRAPA colleague Claudia Guimarães, a plant molecular geneticist focusing on maize, says GCP promoted ‘products’, which also echoed the mission statement of EMBRAPA’s Maize & Sorghum research centre.

The centre’s mission is to: ‘Generate, adapt and transfer knowledge and technology that allows for the efficient production and use of maize, sorghum, and natural resources as well as promotes competitiveness in the agriculture sector, sustainable development, and the well-being of society.’

GCP, says Claudia, “wanted to extract something else from the science – products – the idea of a real, touchable product. You have to have progress: germplasm, lines, markers; they are quite practical things.

“The major goal of GCP is to deliver products that can improve people’s lives worldwide. So it needs to be readily available and useful for other scientists and for the whole community.”

GCP wanted to ensure that research products could and would be adopted, adapted and applied for the ultimate benefit of resource-poor farmers. The Programme therefore set out to catalyse interactions between the various players who are needed to bridge the gap between strategic research in advanced labs and resource-poor farmers.

GCP and EMBRAPA were both working towards tangible applied outcomes, says Claudia: “GCP was not only giving you money, they are really serious about what are you doing: ‘Did you deliver everything you promised?’”

Claudia delivered. She and her team at EMBRAPA were able to find an important aluminium-tolerance gene in maize similar to the sorghum gene. This outcome provided the basic materials for molecular-breeding programmes focusing on improving maize production and stability on acidic soils in Africa and other developing regions.

Photo: L Kochian

Maize trials in the field at EMBRAPA. The maize plants on the left are aluminium-tolerant while those on the right are not.

Multifaceted and tangible results

Through further GCP funding, EMBRAPA researchers Robert Schaffert and Sidney Parentoni were able to work together with two researchers from Kenya, Dickson Ligeyo and Samuel Gudu, to develop a breeding programme to combine the improved Brazilian germplasm with locally adapted Kenyan materials. A new base of improved germplasm was established for Kenyan breeders, which allowed the development of varieties adapted to acidic soils in Kenya.

Sidney, a maize breeder for GCP projects and now the deputy head of research and development for EMBRAPA Maize & Sorghum, says that the benefits of being part of GCP are multifaceted: “It was very important, not only for EMBRAPA as an institute, but also individually for each of the participants that had the opportunity to interact with partners in different parts of the word,” says Sidney.

Photo: Bioversity International

A Kenyan farmer with her sorghum crop.

“Each of them adds a piece to build the results achieved by GCP, which from my perspective promoted a number of advances in the areas of genetics and breeding.

“Technologies such as root image scanning developed at Cornell [University] were transferred to EMBRAPA and allowed us to do large-scale screening in a number of maize and sorghum genotypes with large impacts in phosphorous-efficiency studies.

“Scientists from Africa were trained in breeding and screening techniques at EMBRAPA, and Brazilian scientists had the opportunity to go to Africa and interact with African researchers to jointly develop strategies for breeding maize and sorghum for low-phosphorous and acidic soils.

“These trainings and exchanges of experiences were very important for the people and for the institutions involved,” says Sidney.

Sustainable partnerships to break ground for groundnut

Photo: N Palmer/CIAT

Groundnut

Soraya Leal-Bertioli is a researcher in the EMBRAPA Genetic Resources & Biotechnology centre. She works on groundnut (also known as peanut), and formed part of the GCP team working on groundnut with tolerance to drought and resistance to diseases and fungal contamination. She concurs that GCP united researchers from all over the globe in a common goal.

“GCP not only identified groups, but it went out, searched for people and invited contributions, offered resources to get them together. GCP brought partnerships to a whole new level,” Soraya says.

“Last time I checked there were 200 partners in 50 countries. No one is able to do that. It required a lot of money, a lot of resources, but the way it was dealt with in GCP was: ‘Let’s reach out for the main players, the ones who have the technology, and also the ones who can use the technology’.

“GCP used the resources for the benefit of the community and brought everybody together.”

Soraya says the traditional way of funding research often had ‘no structure’.

“Sometimes a university or funding body receives a large amount of money and decides to build something, a new institute in the middle of the jungle somewhere, but they don’t have anybody to run it; it is not sustainable.

“What GCP did was help to provide the structure and the agents for the whole system. They helped train the people to run the whole system. This is a very sustainable model, which is very likely to give good results in a much shorter time frame than other programmes.”

Watch Soraya – and other members of the team – discuss the complex personality of groundnut and groundnut research in our video series:

Genetic stocks AND people are products

The products and outcomes of the collaboration with GCP have included both the tangible and the not-so-tangible. Sidney says that a large quantity of Brazilian improved maize and sorghum lines tolerant to acidic soils has been developed over the years at EMBRAPA.

“These materials were shared with partners in Africa, and this was a major contribution to Kenyan farmers, as part of this collaborative work done in the scope of GCP.

“To be part of the programme has been very important for EMBRAPA’s research team. It has given us the opportunity to interact with a diversity of institutes.”

Sidney mentions institutes they gave worked with through GCP, including Cornell University and Texas A&M University in the US, the Japan International Research Center for Agricultural Sciences (JIRCAS), the International Rice Research Institute (IRRI), the International Maize and Wheat Improvement Center (CIMMYT), and various institutes in Africa, such as Moi University, Kenya, and the Kenya Agricultural and Livestock Research Organisation (KALRO).

Sidney concludes: “In this large network of partnerships, EMBRAPA was able to learn and to share information in a highly productive way.

“From my perspective, the involvement with GCP projects allowed me to grow as a researcher and as a person, and also at the same time to share and to acquire new knowledge in a number of areas. I think it was a ‘win-win’ interaction for all the participants.”

Many of the products generated within the scope of GCP, such as markers and germplasm, are already available within EMBRAPA’s breeding programmes. Avenues for further research have been paved based on the GCP achievements, and these new research lines will be continued within new projects.

As Claudia says: “The strong partnerships built along the way with GCP will be maintained by us joining with new research teams from other institutes and countries to work on new projects.”

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Mar 262015
 

 

Photo: R Cheung/Flickr

Wheat growing in China.

For as long as peoples and countries have traded wheat, drought has continually played a part in dictating its availability and price. Developed countries have become more able to accommodate the bad years by using intensive agricultural practices to grow and store more wheat during more favourable years. However, farmers, traders and consumers are still at the mercy of drought when it comes to wheat availability and prices.

A recent example where drought in just one country inflated the world’s wheat prices was in the People’s Republic of China during 2010–11.

For almost six months, eight provinces in the north of China received little to no rain. Known as the breadbasket of China, these eight provinces grow more than 80 percent of the country’s total wheat and collectively produce more wheat than anywhere else in the world.

It was the worst drought to hit the provinces in 60 years.

With over 1.3 billion mouths to feed, China’s demand for wheat is high and ever increasing. When this demand was coupled with the reduced wheat yield caused by the severe 2010–11 drought, wheat prices around the world rose. While this price rise was beneficial for wheat growers in other countries, it made wheat unaffordable for many consumers and traders in developing nations.

Although this was a one-in-60-year event, previous droughts had already made locals question the sustainability of wheat production in this naturally dry region of China, where water consumption has increased in the past 50 years due to intensive agriculture, industry and a growing and increasingly urbanised population.

Wheat growers and breeders know they need to find wheat varieties and apply practices that will help them adapt to and tolerate drier conditions and still produce sustainable yields.

Luckily, they have help from a community of breeders around the world.

Photo: E Zotov/Flickr

An Uyghur baker displays his bread in Kashi, Xinjiang, China.

Sharing knowledge to improve breeding efficiency and sustainability

In March 2009, 70 international plant breeding leaders and experts from the public and private sector converged in Montpellier, France, as part of a CGIAR Generation Challenge Programme (GCP) initiative to draw up roadmaps to improve plant-breeding efficiency in developing countries.

Richard Trethowan, professor in plant breeding at the University of Sydney, Australia, remembers the meeting distinctly. “We all got together and thought how we could use what we had learnt during the first phase of GCP [2004–2009] – all the genetics and molecular-breeding work – to deliver new varieties of crops, particularly in countries where it will have the greatest impact.”

The resulting roadmap for wheat became the GCP Wheat Research Initiative (RI), with Richard as Product Delivery Coordinator. It had two very clear destinations in mind: China and India.

Richard explains why China and India were targeted – as the world’s two wheat-production giants – in the video below.


Wheat Research Initiative developed capacity and infrastructure in China and India The Wheat RI aimed to integrate genetic diversity for water-use efficiency and heat tolerance into Chinese and Indian breeding programmes. Some aspects of the RI sprang from work led by Francis Ogbonnaya of the International Center for Agricultural Research in the Dry Areas (ICARDA) and by Peter Langridge of the Australian Centre for Plant Functional Genomics (ACPFG). Jean-Marcel Ribaut, GCP Director, says of the work: “The GCP’s RI approach was not about large impacts in the short term. Rather, what GCP demonstrated was definitive proof-of-concept of the power of molecular breeding to increase crop productivity, thereby improving food security. Other agencies are now able to upscale and outscale the proven concept at the national, or even at the regional level.”

Like China, India is an extremely water-stressed country, with the water table in many places falling at an alarming rate. In North Gujarat alone, an established wheat district in western India, the water table is reported to be dropping by as much as six metres per year.

Delivering wheat varieties that have improved water-use efficiency and higher tolerance to drought will have the greatest impact in these countries, given they are the two largest producers of wheat worldwide.

“Even though the Initiative is set to conclude in 2015, the outcomes have already been absolutely phenomenal for such a short time-bound project, given that wheat is such a complex plant to work with,” exclaims Richard. “While we are still a few years away from releasing new drought-tolerant varieties, we have been able to develop systems and build capacity to reduce the time it takes to develop and release these varieties.”

Tapping into genetic diversity to enhance wheat’s drought and heat tolerance

Photo: Rasbak/Wikimedia Commons

Spikes of emmer wheat.

One project that impressed Richard was that led by Satish Misra, GCP Principal Investigator and senior wheat breeder at Agharkar Research Institute, Pune, India.

In a collaboration with the University of Sydney, Australia, and the International Maize and Wheat Improvement Center (CIMMYT), the project identified novel genes associated with drought- and heat-tolerance traits in ancestral wheat lines (of emmer wheat).

Emmer wheat is a minor crop grown mainly in marginal lands, where farmers can produce a small harvest but nowhere near the yield of more elite cultivated lines. Satish explains that emmer wheat lines are very useful for breeders because they have a larger diversity of novel genes than more popular wheat types, such as durum or bread wheat.

Photo: X Fonseca/CIMMYT

Durum wheat spike.

“Durum lines are more commonly used by breeders because of their high yield and hard grain, which is used to make bread wheat and pasta,” Satish says. “However, because of their popularity and continual use in breeding, durum wheat lines have become less and less diverse with years of cultivation.”

The first task was to identify emmer lines that might have genes for drought and heat tolerance. Satish says that CIMMYT played an important part in this process. “They gave us access to their gene bank, which contains almost 2,000 emmer lines. More importantly, they helped us develop a reference set that encapsulated all the diversity found in the emmer lines they had.”

A reference set reduces the number of choices that breeders have to search through, from thousands down to a few hundred – in this case, 300 emmer lines.

“CIMMYT also developed 30 synthetic emmer wheat lines by crossing wild emmer wheat species with domesticated wheat species,” says Satish. “The synthetic lines contain the novel drought- and heat-tolerance genes.”

Satish and Richard’s teams crossed these synthetic lines with durum wheat lines and identified 41 resulting lines with high levels of stress tolerance. These are undergoing further evaluation in India and Australia.

“What Satish has been able to do in five years is amazing and is currently having a big impact in wheat breeding in India and Australia,” says Richard. “We’ve had local breeding companies here in Australia come to us requesting the lines we developed. The same is happening in India, too.”

Reaping existing skills  For Richard, the preliminary success of the Wheat RI is due, at least in part, to the speed with which national breeding programmes in both China and India are learning and incorporating new molecular-breeding techniques. “This was another reason why we chose to focus on China and India: they had the infrastructure and human capacity to start doing this almost immediately,” says Richard. “In other countries where GCP is investing, more time is going into teaching breeders the basics of molecular breeding and genetics. In China and India, they already have that basic understanding and are able to quickly incorporate it into their current programmes.”

Reaping existing skills

Photo: R Pamnani/Flickr

A baker butters naan bread in Hyderabad, India.

For Richard, the preliminary success of the Wheat RI is due, at least in part, to the speed with which national breeding programmes in both China and India are learning and incorporating new molecular-breeding techniques.

“This was another reason why we chose to focus on China and India: they had the infrastructure and human capacity to start doing this almost immediately,” says Richard. “In other countries where GCP is investing, more time is going into teaching breeders the basics of molecular breeding and genetics. In China and India, they already have that basic understanding and are able to quickly incorporate it into their current programmes.”

This does not mean, however, that the work is not focused on building capacity, given that molecular breeding is still a relatively new concept for many breeders around the world.

Ruilian Jing says the China project is continually working to educate and train wheat breeders in molecular-breeding techniques.

“When we started the project, we found that most institutions that focus on wheat breeding in China had the equipment to do marker-assisted breeding but were unsure how to use it,” says Ruilian, professor in plant breeding at the Chinese Academy of Agricultural Sciences (CAAS) and Principal Investigator for the Wheat RI’s drought-tolerant wheat project in China.

Much of Ruilian’s work in China has been in educating these breeders so they can start achieving outcomes.

Younger researchers taking a lead

Ruilian explains that those leading the charge to become educated in molecular-breeding techniques are young researchers, including seven PhD students and one Master’s student supported by the project in China.

One such researcher who is enthusiastically applying these new approaches is Yonggui Xiao, a molecular plant breeder at the Institute of Crop Science, CAAS.

“Working as part of this GCP project gave me my first opportunity to practice using molecular-breeding techniques to improve the quality and yield of wheat under drought conditions,” says Yonggui.

“We have so far successfully used several molecular markers to produce an advanced variety, with higher yield and preferred qualities [taste, grain colour] under water stress, and this will be released to farmers [in 2015].”

Photo: R Saltori/Flickr

Women of the Nakhi people harvest wheat in Songzanlinsi, Yunnan, China.

Yonggui is now expanding the application of the technology to develop varieties with resistance to powdery mildew, a fungal disease that can reduce wheat yields and quality during non-drought years. “Overall, we have been impressed by how these new techniques complement our conventional breeding techniques to improve selection efficiency, in turn reducing the time and costs of producing advanced varieties,” says Yonggui.

Success stories like these make Ruilian’s job easier as she tries to encourage more and more plant breeders to experiment with these new breeding techniques.

At the same time, she is impressed by this new generation of molecular wheat breeders who will ensure that these techniques benefit wheat research in many years to come: “This form of capacity, the human capacity, which we are building, is what will leave the largest legacy in China and help this technology spread from generation to generation and crop to crop.”

Overcoming complex traits, genes and wary breeders

Photo: CCAFS

Wheat farmer in India.

Across the Himalayas, Ruilian’s Indian counterpart, Vinod Prabhu, is just as pleased with the progress and results his team are producing.

“Over the last five years, we have discovered several water-use efficiency traits and their related genes, bred new lines to incorporate the genes and traits and run national trials, all of which would be unheard of using only conventional breeding practices,” says Vinod, Head of the Genetics Division at the Indian Agricultural Research Institute in New Delhi and the Principal Investigator for the Wheat RI’s drought-tolerant wheat project in India.

By the end of the projects in November 2015, partners in China and India will deliver 15–20 new wheat lines with drought and heat tolerance, adapted to each country’s conditions. An additional target for both China and India is to produce four wheat varieties with improved water-use efficiency and higher heat tolerance. These varieties will have the potential to cover about 24 million hectares and minimise yield loss from heat or drought, or both, by up to 20–50 percent.

Vinod confides that all these outcomes are far more than what he initially expected they would achieve: “When we started, we had a lot of reservations about the complexity of breeding for drought tolerance in wheat as well as the acceptance and uptake of these new breeding techniques by conventional breeders.”

Vinod’s primary role has been to coordinate the Indian centres working on the project (see box at end). But he has also been working to convince Indian plant breeders that these unconventional, new breeding techniques will improve their efficiency and aid in their quest to breed for heat- and drought-tolerant wheat varieties.

“Many world-leading wheat breeders were wary at first, but they have definitely started to see the merit in using the technology to enhance their conventional methods as we edge closer towards releasing new varieties in such a short time,” says Vinod.

Photo: N Palmer/CIAT

Wheat seed ready for planting in Punjab, India.

Incorporating conventional methods

An aspect of the Wheat RI that Ruilian and Vinod have been continually promoting is the importance of conventional breeding methods. “These new molecular-breeding techniques are only a small part of the whole breeding process,” says Ruilian. “Yes, they provide a big impact, but in the grand scheme of things they need to be viewed as one tool in a breeder’s tool box.”

Conventional vs marker-assisted breeding To conventionally breed a new wheat variety, two wheat plants are sexually crossed. The aim is to combine the favourable traits from both parent plants and exclude their unwanted traits in a new and better plant variety. This is achieved by selecting the best plants from among the progeny over several generations. Marker-assisted breeding allows breeders to be much more efficient and targeted in their activities. It still requires breeders to sexually cross plants, but they can use genetic information to tell them which plants have particular genes for useful traits, which helps them to choose which parent plants to cross, and then to confirm which of the progeny have inherited the desired gene without necessarily growing and phenotyping all of them under conditions that would express that trait.

For more information on conventional versus molecular breeding, or marker-assisted breeding, see our quick guide here on the Sunset Blog.

Phenotyping: How to manage a subjective process

One of the most important processes of the Wheat RI, and plant breeding in general, is phenotyping: measuring and recording observable characteristics of the plant such as drought tolerance or susceptibility to pests and diseases. Breeders phenotype the plants they have developed to see which ones have the traits they are interested in and also – for molecular breeding to be possible – to establish links between specific genes and specific traits.

Unfortunately, phenotyping has caused a bit of trouble for both Chinese and Indian partners. The challenge stems from the fact that one person’s observations about a plant’s phenotype or characteristics may not be the same as another person’s.

“This is always a challenge for any collaborative plant-breeding project,” says Vinod. “Unless all trials are inspected by one person, there will always be a risk of inconsistent observations.

Photo: CIMMYT

Scientists from South Asia learn phenotyping on a training course at CIMMYT.

To help overcome this inconsistency, one of the first activities of the Wheat RI was to develop phenotyping protocols that allowed researchers in different research institutes and countries to collect comparable data. GCP enlisted Matthew Reynolds, a wheat physiologist at CIMMYT, to help with this.

“Each breeder has their own ways to do things, so it’s important to develop standardised protocols, particularly for a transnational project like this,” explains Matthew. “We developed a few standardised phenotyping manuals and travelled to China to give some intensive hands-on training.”

This problem is not unique to China and India. Another GCP wheat project is providing promising results to help overcome the risk of inconsistency and increase the efficiency and accuracy of phenotyping. Led by Fernanda Dreccer, based at Australia’s Commonwealth Scientific and Industrial Research Organisation (CSIRO), in collaboration with the International Center for Agricultural Research in the Dry Areas (ICARDA), the project is developing a reliable phenotyping approach to detect drought-adaptive traits in wheat crops using cheap and simple tools.

“For example, using just a camera you can analyse crop cover, which is an important trait for shading the crop and/or trapping heat,” says Fernanda. “The idea was to test different non-invasive, low-cost tools and compare them to find something that would provide accurate and useful data related to identifying drought-tolerance traits.”

Another important aspect of phenotyping that Fernanda’s project is helping with is constant and consistent analysis of a crop’s surroundings. “It’s just as important to measure the environment of the crop as it is [to measure] the crop itself to make a correlation between an environmental impact and a plant’s reaction,” says Fernanda.

Since the static nature of single observations can give a misleading or incomplete picture, Fernanda’s team is integrating live crop, weather and soil data through mobile sensors in the field with the aim of producing constant phenotypic information. “This will provide new insights into the interaction between the genotype and the environment. This in turn will help to accelerate the detection of wheat genotypes better suited to cope with drought.”

Photo: R Martin/CIMMYT

A young farmer in her wheat field in India.

Managing the tsunami of phenotyping data

Although a plant breeder’s work should be simplified and made more efficient by combining molecular-breeding technologies with advanced phenotyping techniques and protocols, the reality is not necessarily so easy.

There are many steps to the plant-breeding puzzle, all of which produce data. The more advanced the techniques and – in the case of wheat – the more complex the plant’s genome, the more pieces of data breeders need to sift through to find solutions.

Before the Wheat RI started, Richard saw that this impending tsunami of data was going to be a problem in both China and India: “Both countries had the skills to carry out these advanced techniques, but they didn’t have in place a strong culture of data management.”

This problem is by no means unique to China and India, Richard says: “Most of the time, plant breeders keep a log of all their data in a book or Excel sheet. However, these data often get lost once a project is completed.”

GCP recognised this problem before the RIs began and has, since 2009, been developing the Breeding Management System (BMS) – a suite of interconnected software designed to manage the mass of data – as part of its Integrated Breeding Platform (IBP).

“The BMS is the first tool that can help breeders record and collate their data in a coordinated way,” says Richard. “This is vital in a project like this, which has several institutes across three countries working towards a similar product.”

Vinod agrees with Richard, adding that the BMS was relatively easy for his Indian partners to learn and use: “The BMS is great as we have no way of losing data.”

Rolling out the BMS in China, though, has been more difficult due to the language barrier. Ruilian explains: “We are now working towards translating the IBP, but it will be an ongoing challenge as the platform continually changes and is updated.”

Ruilian is optimistic that a translated BMS will become a viable tool for Chinese breeders in the future. “The more that we collaborate with other countries, the more a tool like this becomes important to have.”

Watch Richard on adoption of IBP tools in the video below.

Friendly competition helping inspire India’s wheat breeders

Vinod credits two things for the successful development of new wheat varieties and integration of new breeding techniques and data-management systems: a clear, logical plan and friendly competition between China and India to breed the first new drought-tolerant varieties.

“The initial plan, which Richard helped develop in Montpellier, was logical and well thought out. Although we initially thought it was overambitious in its objectives, we have been able to meet them so far, which is a great credit to the team and their enthusiasm to try these new technologies and see for themselves the benefits first hand.

“What has also helped is our competitive spirit, as we would like to achieve the objectives before the Chinese breeders do. Our breeders are always asking me for updates on how China is progressing!” Vinod adds, with a chuckle.

Ruilian agrees with Vinod’s assessment, adding: “The project would not have been as successful if it was solely national. It needed the international collaboration and friendly competition to help build confidence and drive.”

For Richard this international collaboration, between two very different and proud cultures, allowed the project to broaden its scope and troubleshoot quicker than usual.

“They [the Chinese and Indian researchers] think about problems in different ways. When you get a group of people in a room from different backgrounds, you can come up with great integrated plans, things you would never have come up with within just a national team,” says Richard.

Watch Richard on the beauty of diversity in research partnerships in the video below.

Securing wheat production into the future

With the project concluding in 2015, both the Chinese and Indian researchers are working towards completing national trials and releasing their new, advanced drought-tolerant varieties to farmers and other breeders. However, for Richard, the impact of the Wheat RI may not be fully recognised for 10–20 years.

“The initial new varieties that both China and India develop will help farmers in the short term. However, as both countries become more advanced in using the technology, future varieties are sure to be more and more robust. What’s more, these techniques and tools are sure to filter through to other national wheat-breeding programmes, as well as to other crops.”

In the case of wheat, new drought-tolerant varieties will help secure both China’s and India’s wheat industries, helping to stabilise wheat yields, and consequently prices, the world over. These new varieties may not be the silver bullet for eliminating the risks of drought, but they will go a long way to mitigating its impact.

Photo: Rosino/Flickr

Donkeys bring home the wheat harvest in Qinghai, China.

The GCP Wheat Research Initiative involved 10 institutes from China, India and Australia: China – Chinese Academy of Agricultural Sciences (Institute of Crop Science; National Key Facility for Crop Gene Resources and Genetic Improvement) Hebei Academy of Agricultural Sciences Shanxi Academy of Agricultural Sciences  Xinjiang Academy of Agricultural Sciences India – Indian Agricultural Research Institute Punjab Agricultural University Agharkar Research Institute  National Research Centre on Plant Biotechnology Jawaharlal Nehru Krishi Vishwa Vidyalaya Australia – Plant Breeding Institute, University of Sydney The Wheat RI built on several previous GCP projects conducted by the International Maize and Wheat Improvement Center (CIMMYT) and International Center for Agricultural Research in the Dry Areas (ICARDA).

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Mar 192015
 
Photo: N Palmer/CIAT

A farmer harvests her pearl millet crop in Ghana’s Upper West Region.

Pearl millet is the only cereal crop that can be grown in some of the hottest and driest regions of Asia and Africa. It is a staple provider of food, nutrition and income for millions of resource-poor people living on these harsh agricultural lands.

Even though pearl millet is well adapted to growing in areas characterised by drought, poor soil fertility and high temperatures, “there are limited genetic tools available for this orphan crop,” reported researcher Tom Hash at the International Crop Science Congress 10 years ago.

“The people who relied on this crop in such extreme environments had not benefitted from the ‘biotechnology revolution’, or even the ‘green revolution’ that dramatically increased food grain production on irrigated lands over a generation ago,” adds Tom, now Principal Scientist (Millet Breeding) in the Dryland Cereals Research Program of the International Crops Research Institute for the Semi-Arid Tropics (ICRISAT). This lack of research dividends was despite the fact that pearl millet is the sixth most important cereal crop globally.

It was at this time – in 2005 – that the CGIAR Generation Challenge Programme (GCP) stepped up to invest in more genetic research for pearl millet (along with finger and foxtail millet).

Photo: S Mann/ILRI

Newly harvested pearl millet heads in Niger.

The use of genetic technologies to improve pearl millet had already made some advances through work carried out in the United Kingdom. The GCP initiative was established to improve food security in developing countries by expanding such available genetic work to create crops bred to tolerate drought, disease and poor soils.

With financial support from GCP, and with the benefit of lessons learnt from parallel GCP genetic research, ICRISAT scientists were able to develop more advanced tools for breeding pearl millet.

Pearl millet is used for food for humans and animals and is an essential component of dryland crop-livestock production systems like those of the Sahel region of Africa. It is a main staple (along with sorghum) in Burkina Faso, Chad, Eritrea, Mali, Niger, northern Nigeria, Senegal and Sudan. It has the highest protein content of any cereal, up to 22 percent, and a protein digestibility of about 95 percent, which makes it a far better source of protein than other crops such as sorghum and maize. Pearl millet grain is also a crucial source of iron and zinc. Pearl millet is the most widely grown millet (a general term for grain harvested from small-seeded grasses), and accounts for approximately 50 percent of the total world millet production. It has been grown in Africa and South Asia, particularly in India, since prehistoric times and was first domesticated in West Africa. It is the millet of choice in hot, dry regions of Asia, Africa and the Americas because it is well adapted to growing in areas characterised by drought, poor soil fertility and high temperatures; it even performs well in soils with high salinity or low levels of phosphorous. In short, thanks to its tolerance to harsh environments, it can be grown in areas where other cereals such as maize or wheat do not survive or do not yield well.

Protein in pearl millet ‘critical’ for nutrition

Photo: P Casier/ICRISAT HOPE

A farmer harvests millet in Mali.

Mark Laing, Director of the African Centre for Crop Improvement (ACCI) at the University of KwaZulu-Natal in South Africa, says the GCP-supported work on pearl millet will have long-term impacts.

He says it is the high protein content of pearl millet that makes it such a crucial crop for developing countries – in Africa, this is the reason people use pearl millet for weaning babies.

“It was interesting to us that African people have used pearl millet as a weaning food for millennia. The reason why was not clear to us until we assessed the protein content,” says Mark. “Its seed has 13–22 percent protein, remarkable for a cereal crop, whereas maize has only eight percent protein, and sorghum has only two percent digestible protein.”

Photo: S Kilungu/CCAFS

Pearl millet growing in Kenya.

Tom Hash agrees, adding: “More importantly, pearl millet grain has much higher levels of the critically important mineral micronutrients iron and zinc, which are important for neurological and immune system development.

“These mineral micronutrients, although not present in a highly available form, can improve blood iron levels when used in traditional pearl millet-based foods. Pearl millet grain, when fed to poultry, can provide a potentially important source of omega-3 fatty acids, which are also essential for normal neurological development.”

Pearl millet endowed with genetic potential

Photo: AS Rao/ICRISAT

A farmer with his pearl millet harvest in India.

In a treasure-trove of plant genetic resources, thousands of samples, or accessions, of pearl millet and its wild relatives are kept at ICRISAT’s gene banks in India and Niger.

For pearl millet alone, in 2004 ICRISAT had 21,594 types of germplasm in its vaults at its headquarters in India. This represents a huge reservoir of genetic diversity that can be mined for data and for genetic traits that can be used to improve pearl millet and other crops.

Between 2005 and 2007, with support from GCP, scientists from ICRISAT set to work to do just that, mining these resources for qualities based on observed traits, geographical origin and taxonomy.

Hari D Upadhyaya, Principal Scientist and Director of Genebank at ICRISAT, led the task of developing and genotyping a ‘composite collection’ of pearl millet. To do this, the team created a selection that reduced 21,594 accessions down to 1,021. This collection includes lines that are tolerant to drought, heat and soil salinity; others resistant to blast, downy mildew, ergot, rust and smut; and accessions resistant to multiple diseases.

Photo: C Bonham/Bioversity International

A traditional pearl millet variety growing in India.

The collection also includes types of pearl millet with high seed iron and zinc content (from traditional farmer varieties, or landraces, from Benin, Burkina Faso, Ghana and Togo), high seed protein content, high stalk sugar content, and other known elite breeding varieties.

The final collection comprised 710 landraces, 251 advanced breeding lines, and 60 accessions from seven wild species.

The GCP-supported scientists then used molecular markers to fingerprint the DNA of plants grown from the collection. Molecular markers are known variations in the sequence of the genetic code, found in different versions within a species, which act as flags in the genome sequence. Some individual markers may be associated with particular useful genes, but markers are useful even without known associations, as the different flags can be compared between samples. In the pearl millet research, scientists searched for similarities and differences among these DNA markers to assess how closely or distantly related the 1,021 accessions were to each other.

This was not only a big step forward for the body of scientific knowledge on pearl millet, but also for the knowledge and skills of the scientists involved. “The GCP work did make some significant contributions to pearl millet research,” says Tom, “mainly by helping a critical mass of scientists working on pearl millet to learn how to appropriately use the genetic tools that have been developed in better-studied fungi, plants and animals (including people).”

GCP extends know-how to Africa

Photos: N Palmer/CIAT

Comparisons of good and bad pearl millet yields in Ghana’s Upper West Region, which has suffered failed rains and rising temperatures.

The semiarid areas of northern and eastern Uganda are home to a rich history and culture, but they are difficult environments for successful food production and security.

In this region, pearl millet is grown for both commercial and local consumption. Its yields, although below the global average, are reasonable given that it is grown on poor sandy soils where other crops fail. Yet despite being a survivor in these harsh drylands, pearl millet can still be affected by severe drought and disease.

GCP helped kick-start work to tackle these problems. With financial support from GCP, and through ACCI, Geofrey Lubade, a scientist from Uganda, was able to study and explore breeding pearl millet that would be suitable for northern Uganda and have higher yields, drought tolerance and rust resistance.

Geofrey now plans to develop the best of his pearl millet lines for registration and release in Uganda, which he expects will go a long way in helping the resource-poor.

But Geofrey’s success is just one example of the benefits from GCP-support. Thanks to GCP, Mark Laing says that his students at ACCI have learnt invaluable skills that save significant time and money in the plant-breeding process.

“Many of our students, with GCP support, have been involved in diversity studies to select for desirable traits,” says Mark – and these students are now working on releasing new crop varieties.

He says that African scientists directly benefitted from the GCP grants for training in biotechnology and genetic studies.

Their work, along with that of a number of other scientists, will have a huge impact on plant breeding in developing countries – long term.

Photo: N Palmer/CIAT

A farmer inspects his millet crop in northwest Ghana.

As Mark explains, once breeders have built up a head of steam there is no stopping them. “Plant breeders take time to start releasing varieties, but once they get started, then they can keep generating new varieties every year for many years,” he says. “And a good variety can have a very long life, even more than 50 years.

“We have already had a significant impact on plant breeding in some African countries,” says Mark. But perhaps more importantly, he says, the work has changed the status of plant breeding and pearl millets as a subject: “It used to be disregarded, but now it is taken seriously as a way to have an impact on agriculture.”

For research and breeding products, see the GCP Product Catalogue and search for pearl millet.

Mar 172015
 

 

Photo: IRRI

Harvesting rice by hand in The Philippines.

Rice plays a key role in global food security, particularly in Asia, where 90 percent of the world’s rice is grown and eaten. By 2050, Asia’s population is estimated to grow by one billion to 5.2 billion people, who will continue to depend on rice as their major staple food.

But with rising demand for rice has also come increasing salinity, droughts and other stresses, along with decreasing areas of land available for farming the crop.

And that’s why the CGIAR Generation Challenge Programme (GCP) placed a major focus on rice throughout its 10 years of existence.

Key ingredient in the rice research fest was GCP’s relationship with the International Rice Research Institute (IRRI), headquartered in The Philippines. GCP supported IRRI in its endeavours to use the latest molecular plant-breeding techniques, along with traditional plant-breeding tools, to develop rice crops better able to cope with various stresses and still be productive.

“These ‘super’ crops will revolutionise rice farming,” says IRRI Director General Robert Zeigler, who was also the first Director of GCP.

For more on GCP’s rice research see our Sunset Story ‘The power of rice unlocked’.

Rice that can survive increasingly salty water

Climate change is one of the major threats facing rice production. As sea levels rise, salt water enters further up rivers with the high tides and affects rice production areas.

Each year in Bangladesh, during the boro rice season from November to May, salinity is so high that a white film of salt covers the country’s coastal paddy fields. For Bangladeshi farmers, this white colour is a warning sign that their land is ‘sick’. Around the world, Bangladesh, India, Myanmar and parts of Africa are most affected by increasing salinity.

Right from the beginning of GCP, salinity was a problem firmly on the rice research agenda.

Photos: IRRI

Highly saline soils in India (left), and a close-up showing a surface crust of salt on afflicted soil (right).

Leading this research was IRRI plant physiologist Abdelbagi Ismail, who dreamed of the ‘super’ rice crop that could “tolerate salinity, drought and submergence”.

Abdelbagi has managed and overseen most of the progress made during the discovery of a major genetic region, or quantitative trait locus (QTL), associated with salinity tolerance and named Saltol.

Photo: IRRI

Abdelbagi Ismail examines rice plants in the field in Bangladesh.

Its insertion into well-known rice varieties used by farmers in Bangladesh, Indonesia and The Philippines is part of the revolution taking place in rice research.

Abdelbagi says Saltol was mapped and markers were developed for its use in breeding more salt-tolerant rice varieties. Its salt-tolerance code is now being transferred into several varieties evaluated with IRRI partners in South and Southeast Asia.

“These projects also provided opportunities for both degree training and non-degree training to several of our partners in the countries involved,” he adds.

“Partnerships are crucial for us to build the capacity of the researchers in these countries and to ensure our outputs and outcomes reach the farmers that need them.

“All our partners benefitted from salt-tolerant varieties developed conventionally through this project, and they also provided pipelines for uptake and dissemination by farmers.”

Having developed new lines following the discovery of the Saltol QTL, Abdelbagi’s GCP-supported team trained plant breeders in country programmes to successfully breed for salt tolerance and other stresses.

In this way, Abdelbagi says, they are improving the capacity of researchers in developing countries to take up new breeding techniques, such as the use of molecular markers. “This can reduce the time it takes to breed new varieties, from six to ten years at the moment, down to two or three years,” he says.

This means that benefits to smallholder rice farmers struggling with salinity will happen sooner rather than later. And Abdelbagi credits GCP’s partnership approach, working directly with the countries in need, for the success so far.

“The salt-tolerant varieties are now being widely distributed,” he says. “Some of these varieties have doubled farmers’ productivity in affected areas.

“The work developed technologies of value to our needy farmers.

“We do believe this is the start of a second Green Revolution, especially for those who farm in less favourable areas and that missed this opportunity during the first Green Revolution.”

Partnership approach key to new rice gene for uptake of phosphorus

More than 60 percent of rainfed lowland rice is produced on poor and problem soils, including those that are naturally low in phosphorus. This is an essential for nutrient growing crops, but providing phosphorus through fertilisers is costly and unfeasible for many smallholder rice growers.

Photo: IRRI

IRRI’s Sheryl Catausan prepares the roots of a rice plant for scanning as part of the work of the PSTOL1, phosphorus uptake research team at IRRI.

This problem was the focus of GCP’s rice phosphorus-uptake project led by IRRI molecular biologist Sigrid Heuer.

The project was enormously successful, with its discovery of the PSTOL1 (‘phosphorus starvation tolerance 1’) gene within the Pup1 locus, which was published in the prestigious journal Nature.

“We wanted it in Nature for a couple of reasons,” she says. “To raise awareness about phosphorus deficiency and phosphorus being a limited resource, especially in poorer countries; and to draw attention to how we do molecular breeding these days, which is a speedier, easier and more cost-effective approach to developing crops that have the potential to alleviate such problems.”

Following the PSTOL1 discovery, researchers are now working with developing-country researchers and extension agencies to help them understand how to breed local varieties of rice that can be grown in phosphorus-deficient soils. They are also collaborating with other crop breeders looking to breed similar maize, sorghum and wheat varieties.

Tobias Kretzschmar, a molecular biologist with IRRI, says that GCP’s partnership approach was the key to the project having an impact on the rice farmers who needed it most.

“For me, the collaborations that were forged through these inter-institutional projects made the difference,” he says.

Sigrid agrees: “GCP was always there supporting us and giving us confidence, even when we were not sure.”

Solving the insoluble: a gene for drought tolerance

Rice is a crop that not only needs water, but loves water. So developing a drought-tolerant rice variety is a quest to find a seemingly impossible gene.

However, GCP-supported researchers did just that: they solved the insoluble.

“They were very successful in terms of getting drought tolerance,” says Hei Leung of IRRI, who was GCP Subprogramme Leader for the Comparative Genomics Research Initiative between 2004 and 2007, and also a Principal Investigator for the Rice Research Initiative. “They’re now getting a 1.5 tonne rice yield advantage under water stress. I mean, that’s unheard of! This is a crop that needs water.

“This is one of GCP’s big success stories; that you can actually get drought tolerance is a seemingly impossible task for a water-loving rice plant.”

As Subprogramme Leader, Hei played a critical role in the creation, management, delivery and communication of a wide portfolio of research projects. He credits the nature of how GCP was set up for accelerating the breeding programme for drought-tolerant rice.

“The advantage of GCP is that it is run by a small group of people who can make fast decisions,” he says. “This means they can respond to the needs of researchers: ‘Okay, we are going to invest on that. We’re going to have a meeting on this’.

“The real advantage of GCP is its agility. Usually with other organisations you have new ideas and then have to slave away for a year to get the funding to implement them. But GCP was quick.”

Photo: C Quintana/IRRI

Hei Leung (right) explains rice screening processes to a visiting scholar at IRRI.

IRRI and GCP deliver genetic resources to those who need them most

Tobias says one of the main objectives of GCP and IRRI is to make genetic stocks available to breeders, particularly in developing countries.

“Without that, IRRI would fail in its central mission to reduce hunger and poverty,” he says. “In order to achieve this mission, tight collaboration with our agricultural and extension partners in other countries is the key.”

What is a genetic stock? “A genetic stock is a line that has been created by modern breeders and researchers, using conventional technologies, specifically to address some specified scientific purpose, typically for gene discovery,” explains Ruaraidh Sackville Hamilton, an evolutionary biologist and head of the International Rice Genebank maintained by IRRI in The Philippines. This definition includes the notion of perpetuation (a ‘line’), which is central to genetic stocks: either the materials are genetically stabilised through sexual reproduction, or they can be distributed through vegetative propagation.

In fact, this idea of protecting the future through genetic material was influential in the choice of GCP as a CGIAR Challenge Program name. Hei, who was involved from the start with GCP, talks about the meeting in a Rome pizzeria where participants came up with the name: “When we talk about ‘generation’, we are really talking about the work we do with genetic diversity; it is about the future generation,” he says.

Part of that future generation is about sharing genetic resources or stocks, but first the genetic diversity of such stocks needs to be characterised. Hei remembers that one of the first GCP projects in 2004 brought together researchers in various countries to characterise the genetic diversity of various crops, including rice.

“But everyone was using different genotyping platforms and markers, and the technology back then was not what we have now,” he recalls.

“So we spent a lot of resources getting poor quality data. In a sense, it was a failure. On the other hand, it was also a success because we alerted people to the importance of characterising diversity in every single crop. The whole concept of getting all the national partners doing genetic resource characterisation is a good one.

“We have evolved the technology together over the last 10 years of GCP. Now the country partners feel enabled. They are not scared of the technology.”

Abdelbagi agrees that characterising genetic diversity is essential, and adds that making such genetic stocks readily available to breeders is also vital.

“This has not been an issue before,” he explains. “With the new regulations of germplasm control and intellectual property issues, it became extremely difficult to exchange germplasm with some countries. One important lesson we learnt was to engage in direct discussion with our partners in efforts to influence their policies and guidelines to allow essential exchange of genetic stocks and breeding material, at least at the regional level.”

Abdelbagi adds that another big challenge has been to provide country partners with materials and DNA markers for marker-assisted selection programmes and to make sure these were properly used in breeding programmes.

“We solved this by hosting a workshop at IRRI and with continued visits with GCP collaborators,” he says.

Photo: IRRI

Rice terraces in Ifugao Province in The Philippines.

‘Super’ crops: something ‘magic’ happens

Hei says that the GCP project he’s most passionate about, and one that leaves a lasting legacy, is the development of multiparent advanced generation intercross (MAGIC) populations, which will potentially yield lines that are tolerant to environmental stresses, grow well in poor soils and produce better quality grain.

“MAGIC populations will leave behind a very good resource towards improving different crop species,” says Hei. “I’m sure that they will expand on their own.”

Making MAGIC MAGIC – multiparent advanced generation intercross – allows crop breeders to identify the genes controlling quantitative traits, such as salinity tolerance, by crossing different combinations of multiple parents. The results of these crosses are plants whose genome is a mosaic of their multiple parents. MAGIC has multiple advantages compared with existing approaches, as it permits a more precise identification of genes that are responsible for particular rice traits. Even genes with minor effects can be pinpointed. Standard crosses (between two parents) show a poor correlation between the diversity found in the DNA (genetic diversity) and the diversity of the observable characteristics displayed by the plant (phenotypic diversity) when it grows as part of a crop. Because the MAGIC populations are created from multiple parents rather than by simply crossing two lines, making them more genetically diverse, and are the product of numerous generations of intercrossing the original founders or parent plants, creating greater opportunities for recombination and so ‘milling’ the genetic contributions from the different lines ever finer, scientists are able to more accurately identify the genes underlying important traits.  There are three main advantages of the MAGIC approach compared to existing approaches: 1. It enables scientists to more precisely identify the specific regions of the genome controlling key traits. 2. MAGIC populations incorporate a large proportion of the genetic diversity within elite rice varieties from around the world. 3. MAGIC enables the discovery of the best combinations of genes for important traits.

GCP funded the development of four kinds of rice populations, including indica MAGIC, which is the most advanced of the MAGIC populations developed so far. These populations contain multiple desirable traits, including: blast and bacterial blight-resistance, salinity and submergence tolerance and grain quality.

New generation of researchers working on a new rice revolution

Photo: IRRI

Rice farmer in her field in Rwanda.

Robert Zeigler’s dream of a new rice Green Revolution with ‘super crops’ is coming true, thanks in part to GCP’s focus on combining cutting-edge molecular plant-breeding techniques with conventional plant breeding.

“With all this going for us, the second Green Revolution means we can meet the great challenges ahead with unprecedented efforts that will result in unparalleled impacts,” he says. “This will range from mining the rice genomes for needed traits to developing climate change-ready rice.”

IRRI researchers like Abdelbagi agree that new plant-breeding techniques, such as those fostered by GCP, are making ‘super’ crops more likely: “I’m committed to understand how plants can be manipulated to adapt to, and better tolerate, extreme environmental stresses, which seems more feasible today than it has ever been before.

“GCP-supported work has provided mechanisms for developing varieties with multiple stress tolerances, besides the improvements in yield and quality.”

And for Hei, GCP’s 10-year legacy is not just about the technology but also about the people.

“Over ten years you have three generations of PhD students,” he says. “Many people became a ‘new generation’ scientist through this programme. Many people have benefitted. GCP is one of a kind. I’m just in love with it.”

More links

Mar 102015
 

 

Niaba Témé

Niaba Témé

“I can’t talk enough about the positive stories from the Generation Challenge Programme [GCP]. It initiated something new. I cannot measure its benefits for my country, for myself and for the sorghum-breeding and -producer communities. Right now, GCP has reached its sunset; but for me it is a sunrise, because what we have been left with is so very important.”

Growing up in a farming community in Mali, on the southern edge of the Sahara Desert, plant breeder Niaba Témé knows the ups and downs of farming in the harsh, volatile semiarid regions of Africa.

“I used to love harvesting the millet and helping my mother with her groundnut crops,” he remembers fondly. “We grew other dryland crops too, like sorghum, cowpeas, Bambara nuts, sesame and dah.”

Niaba’s village of Yendouma-Sogol is one of many villages balanced along the edge of the Bandiagara escarpment – 150 kilometres of sandstone cliffs soaring hundreds of metres above the sandy plains below. The region is considered one of the most challenging places in the world to be a farmer. The climate is harsh, with the average daily temperature on the dry, sun-scorched plains rarely falling below 30°C and often exceeding 40°C during the hottest months of the year. With no major water source available for drinking, cropping and livestock husbandry, the threat of drought is ever-present here, as it is across much of Africa’s semiarid landscape.

While much of Mali’s irrigated agriculture relies on water from the River Niger, villages like Niaba’s depend entirely on the 500 or so millimetres of rainfall they receive during the July–August wet season. In the years that the rains didn’t come, Niaba’s family were unable to harvest anything at all. The repeated failure of his parents’ crops – coupled with a natural interest in science – inspired Niaba to embark on a career where he could help farming families like his own defend themselves against the risks of drought and extreme temperatures.

Photo: F Fiondella/CCAFS

Farmland in Diouna, Mali. Farmers here must contend with the Sahel’s dry, sandy soil and whatever limited rainfall the clouds bring to grow sorghum, millet, maize, and other crops.

Niaba’s journey

Niaba’s first big step along the research road was when he enrolled to study agronomy at Mali’s Institut Polytechnique Rural de Formation et de Recherche Appliquée in Eastern Bamako. Within two years he was offered a scholarship to study plant breeding at the International Crops Research Institute for the Semi-Arid Tropics (ICRISAT) in Hyderabad, India. He then worked at the Cinzana Research Station in Mali.

Niaba later spent 11 years in the USA completing a bachelor’s degree, master’s degree and finally PhD in agronomy at Texas Tech University before returning home to Mali in 2007, where he was soon recruited by Mali’s Institut d’Économie Rurale (IER) to take charge of their new biotechnology lab at the Centre Régional de Recherche Agronomique.

His journey with the Generation Challenge Programme began in 2010 when IER received GCP funding to carry out sorghum research in Africa as part of GCP’s Sorghum Research Initiative (RI) launched that same year. The project was a collaboration with ICRISAT and France’s Centre de coopération internationale en recherche agronomique pour le développement (Agropolis–CIRAD; Agricultural Research for Development). With an initial focus on Mali, the project’s results would expand to encompass five other countries in the Sudano-Sahelian region: Burkina Faso, Ethiopia, Kenya, Niger and Sudan.

Sorghum the survivor gets even tougher

Photo: ICRISAT

Hand milling of sorghum grains – an arduous task, mostly carried out by poor women in the drylands of Africa.

Drought-hardy crops such as sorghum are ideal for Mali’s conditions, where more water-intensive crops such as maize simply cannot survive. Millions of poor rural people across Africa depend on sorghum in their day-to-day lives: it is eaten in many forms, used to make alcoholic beverages and as animal fodder, and is converted into biofuel for cooking.

But even sorghum has its limits. While the demand for it has doubled in West Africa in the last 20 years, productivity has generally remained low, with an average yield of only one tonne per hectare for traditional varieties in Mali. This is mostly due to post-flowering drought, poor soils and farming conditions, and limited access to quality, high-yielding seed. As rainfall patterns become increasingly erratic and variable across the world, scientists warn of the need to improve sorghum’s broad adaptability to drought, to ensure future food security in Africa.

The GCP Sorghum RI, with Niaba’s help, aimed to support the development of new breeds of sorghum that could survive better on less water in drought-stricken parts of Africa. It sought to improve sorghum yield and quality for African farmers and, in turn, improve the livelihoods and food security of communities across sub-Saharan Africa.

In 2012, Niaba found himself travelling once again, this time to Australia with IER colleague Sidi B Coulibaly. They spent three weeks working alongside, and training with, Andrew Borrell and his sorghum research team at the Queensland Government Department of Agriculture, Fisheries and Forestry’s (DAFF) Hermitage Research Facility in Warwick.

“We have been collaborating with researchers at DAFF and The University of Queensland since 2009, to introduce what is called the ‘stay-green’ drought-resistant gene into our local sorghum varieties,” says Niaba.

Photo provided by A Borrell

Left to right: Niaba Témé with David Jordan (Australia), Sidi B Coulibaly (Mali) and Andrew Borrell (Australia), visiting an experiment at Hermitage Research Facility in Queensland, Australia.

Niaba’s no longer green when it comes to using stay-green

Stay-green is a drought adaptation trait that allows sorghum plants to stay alive and maintain green leaves for longer during post-flowering drought. This means the plants can keep growing and produce more grain in drier conditions. It has contributed significantly to an increase in sorghum yields, using less water, in north-eastern Australia and southern USA for the last two decades.

GCP’s stay-green project aimed to evaluate the potential for introducing stay-green into Mali’s local sorghum varieties, enriching Malian pre-breeding material for the trait, and training African sorghum researchers, such as Niaba, in the methods of improving yields and drought resistance in sorghum breeding lines from both Australia and Mali.

Photo provided by E Weltzein-Rattunde

A sorghum farmer in Mali.

“In Australia we learnt about association mapping, population genetics and diversity, molecular breeding, crop modelling using climate forecasts, and sorghum physiology,” says Niaba.

Learning to use molecular markers was particularly exciting, he says, “because molecular markers make it easier to see if the plant being bred has the gene related to drought tolerance, without having to go through the lengthy process of growing the plant to maturity and risk missing the trait through visual inspection.”

Niaba says the molecular training he received in Australia complemented previous training he had received through a collaborative GCP-funded project with Agropolis–CIRAD and Syngenta Foundation for Sustainable Agriculture, in which he learnt to use molecular markers to identify and monitor key regions of sorghum’s genome in consecutive breeding generations through a process called marker-assisted recurrent selection (MARS).

A large part of GCP’s focus is building such capacity among developing country partners to carry out crop research and breeding independently in the future, so they can continue developing new varieties with drought adaptation relevant to their own environmental conditions.

“Our time in Australia was an intense but rewarding experience, more so for the fact that between the efforts of Australia and Mali, we have now developed new drought-tolerant crops which will enhance food security for my country,” says Niaba. “Similarly with the help of Agropolis–CIRAD and Syngenta, we are using molecular markers to improve breeding efficiency of sorghum varieties more adapted to the variable environment of Mali.”

Photo provided by A Borrell

Niaba (foreground) examining a sorghum panicle at trials in Mali in 2009.

Sorghum sunrise in Mali

On the back of the MARS project, Niaba successfully obtained GCP funding in 2010 to carry out similar research with Agropolis–CIRAD and collaborators in Africa at ICRISAT.

“In that project, we were trying to enhance sorghum grain yield and quality for the Sudano-Sahelian zone of West Africa using the backcross nested association mapping (BCNAM) approach,” explains Niaba. “This involved using an elite recurrent parent that is already adapted to local drought conditions. The benefit of this approach is that it can lead to detecting elite varieties much faster.”

The approach has the potential to halve the time it takes to develop local sorghum varieties with improved yield and adaptability to drought. The project developed 100 lines for 50 populations from backcrosses carried out with 30 recurrent parents. The lines are now being validated in Mali.

Photo: P St-Jacques/DFATD-MAECD

Agronomists inspect a field of sorghum in Mali.

Niaba says such successful collaborations and capacity development opportunities have been made possible only through GCP support.

“We had some contacts before, but we didn’t have the funds or skills to really get into a collaboration. Now we’re motivated and are making connections with other people so we can continue working with the material we have developed.

“GCP’s time may be ending, but it very much represents a new day – a sunrise for the work we are doing with sorghum here in Mali.”

More links

Photo: N Palmer/CIAT

Sorghum for sale.

Mar 062015
 

 

Photo: IITA

A woman holds yam tubers in her hands in a market in West Africa.

Yam production in West Africa is plagued by unsustainable and suboptimal practices. Most farmers continue to grow local varieties that produce poor yields – and also lack aesthetic qualities that appeal to consumers, such as smooth skin and elegant tuber shape.

For a better future and a sustainable food supply, farmers need access to improved yam varieties that can tolerate changes in the climate and environment, as well as resist pests and diseases. Adopting new practices will also help farmers to increase their yields.

Yams play a key role in the food security, income generation and sociocultural life of at least 60 million people in Africa, where more than 95 percent of the world’s yam supply is produced. Worldwide, the tuber vegetable is grown and consumed across the tropics and subtropics of Asia, the Caribbean, the Pacific, and West and Central Africa. Such is the reliance on yams in parts of Africa that communities hold annual festivals to revere and celebrate the crop. The Igbo people in Nigeria hold a ‘new yam harvest’ festival every year at the end of the rainy season in August or September, when the yams are ready for harvest. People in both Nigeria and Ghana hold the ‘new yam eating’ festival, also known as the ‘hoot at hunger’ festival, which symbolises the end of a harvest and the beginning of the next cropping cycle.

Despite the importance of yams in West Africa, breeding efforts for improved varieties have been limited for a number of reasons. One is that local yam cultivars have different names in different communities, making germplasm management and research difficult. Another obstacle is the constraints on yam growth – the plants have a long growth cycle and are highly susceptible to pests and diseases, poor soil, weeds and drought.

Photo: J Haskins/Global Crop Diversity Trust

Dancers celebrate at a new yam festival in Nigeria.

Unique collaborations get yam research rolling

Photo: J Haskins/Global Crop Diversity Trust

A farmer in his yam field in Nigeria.

In 2004, the CGIAR Generation Challenge Programme (GCP) recognised the need to provide resource-poor farmers in West Africa with yam varieties that combine high yields with drought tolerance, pest and disease resistance, and good tuber quality. The Programme was created to advance plant genetics for 21 crops, with a view to improving the resources and capabilities of local breeders in developing countries. Yams were one of the crops that received funding for the first half of the 10-year Programme.

Robert Asiedu, Principal Investigator for GCP’s project assessing the genetic diversity of yams in West Africa, says the Programme improved yam breeding through its unique collaborations.

“The work was brief but the partnership arrangement was useful,” says Robert, who is Director of Research for Development at the International Institute of Tropical Agriculture (IITA), based in Nigeria.

Photo: IITA

A Nigerian farmer displays her healthy yam tubers.

His GCP-funded team included researchers from Centre de coopération internationale en recherche agronomique pour le développement (Agropolis–CIRAD; Agricultural Research for Development) in France, the International Potato Center (CIP) headquartered in Peru, the International Centre for Tropical Agriculture (CIAT) based in Colombia, the International Crops Research Institute for the Semi-Arid Tropics (ICRISAT) headquartered in India, Chile’s Instituto de Investigaciones Agropecuarias (INIA; Agricultural Research Institute), and the United States Department of Agriculture, plus experts in genome profiling and genetic analysis from Diversity Arrays Technology (DArT) in Australia. DArT provided high-throughput genotyping services that helped to profile yam’s genome.

Andrzej Kilian, DArT’s founder and director, says: “My company had a range of interactions with GCP, and I hope we had some positive impact on the outcomes.”

The researchers used molecular breeding tools – simple sequence repeat markers, or SSRs – to assess the genetic diversity of more than 500 yam accessions from Benin, DR Congo, Côte d’Ivoire, Equatorial Guinea, Gabon, Ghana, Nigeria, Sierra Leone and Togo. The assessment was a huge step forward in expanding the scientific knowledge of yam genetics, and ultimately in identifying suitable material for use in breeding programmes.

Photo: J Haskins/Global Crop Diversity Trust

Walking in yam fields.

IITA research scientist Maria Kolesnikova-Allen, also funded by GCP, says the yam work had two main objectives.

Photo: IITA

Yam vines twist up bamboo staking in a yam field.

“The primary focus of the first projects on yams involving molecular markers was to assess genetic diversity among yams originating from different West African countries and to find relationships between species. This information is important for future breeding and conservation efforts,” she says.

“Also, we were interested in confirming the use of molecular markers for analysis of yams and their potential use in breeding programmes.

“By confirming their usefulness in yam studies, we have offered a robust tool set for further studies on this crop.”

Photo: IITA

A trader displays clean and dried yam tubers at Bodija market, Ibadan, Nigeria.

As a result of the research, she says, “more knowledge and understanding has been achieved in terms of the genetic structure of yam populations in West and Central Africa, providing breeders with important knowledge for accessions selection to be included in breeding programmes.”

The genetic information that has been generated for yams will directly benefit countries in West Africa, according to Maria, “especially with IITA being positioned in the middle of the region and providing expert advice and dissemination of this information to local breeders and farmers.”

As part of her GCP-supported work, Maria supervised West African PhD students Jude Obidiegwu from Nigeria and Emmanuel Otoo from Ghana. Jude, a researcher at the National Root Crops Research Institute (NRCRI) in Nigeria, was responsible for GCP’s work on the genetic diversity of yams. His PhD assessed the genetic diversity of the West African yam collection.

African researchers carry GCP torch forward for yams

Jude is an example of how GCP focussed on fostering a base of experts on the ground in the countries where yams play an important role in people’s lives.

He was a participant in GCP’s Plant Genetic Diversity and Molecular Marker Assisted Breeding workshop held in Pretoria in June 2005. There he learned genomic DNA extraction methods, genetic and quantitative trait locus (QTL) mapping, development of core collections, and scientific proposal writing.

Photo: IITA

Woman counting money from the sales of yams at a yam market in Accra, Ghana.

“Our students at PhD level from Nigeria and Ghana were the main drivers of the projects at laboratory and field experiments level,” says Maria.

“Being involved in the projects allowed them to gain international exposure in their respective research fields and later advance their scientific career, becoming fully fledged yam scientists in their own right.

“If there be any hope of applying advanced genetics and genomics tools to the improvement of yam, it is researchers like Jude who will be the foot soldiers of that work in Africa.”

Photo: J Haskins/Global Crop Diversity Trust

A drummer adds his music to a new yam festival in Nigeria.

Maria feels there are strong foundations for further development of yam’s genetic resources after GCP’s sunset at the end of 2014.

“I would like to hope the future is bright,” she says. “As programmes for reducing hunger and poverty are multiplying and gaining momentum worldwide, I am sure the research on staple crops will be given much-needed financial support.

“I strongly believe in a partnership approach,” she maintains, drawing an analogy between GCP’s focus on crop genetics and the Human Genome Project that involved more than 300 partners collaborating between 1990 and 2003 to identify, map and sequence the human genome.

Robert agrees, forecasting that: “New projects will raise the capacity for yam breeding in West Africa by developing high-yielding and robust varieties of yams preferred by farmers and suited to market demands.”

Photo: IITA

A woman offers yam flour (known as elubo isu) for sale in Bodija market, Ibadan, Nigeria.