Generation Challenge Programme
GCP website
Integrated Breeding
IBP website
GCP Blog
GCP blog
  Connect with us GCP on Facebook GCP on Twitter GCP on LinkedIn Subscribe to GCP Newsletter Subscribe to GCP RSS feeds
Oct 192015
 

 

Photo: ICRISAT

Precious sorghum seed diversity.

Humans are a protective species. We like to hoard away our precious items in vaults and safes made of concrete and steel, safe from thieves and catastrophes.

One not-so-obvious precious item, which many people take for granted, is seed. Without seeds, farmers would not be able to grow the grains, legumes, vegetables and fruits we eat.

For centuries, farmers have harvested seeds to store and protect for planting the following year. Most of the time, farmers will only keep seeds harvested from plants that have excelled in their environment – that have produced high yields or have favourable qualities such as larger or tastier grain. This simple iterative process of selecting primarily for high yields means that many crops today are closely related genetically, which can make them more vulnerable to evolving diseases and pests.

Without diversity, a severe epidemic can completely wipe out a farmer’s crop — and even a whole region’s crop. One of the best-known historical examples of just such a disastrous crop failure is the Irish Potato Famine of the 19th century, when potato blight disease caused extensive death, human suffering and social upheaval. A number of crops around the world are in similar danger today, including wheat, threatened by the Ug99 strain of stem rust disease, to which almost all the world’s wheat is susceptible, and cassava, menaced by African cassava mosaic virus (ACMV).

The solution – genetic diversity

Plant breeders are looking at ways to increase diversity among cultivated crops, mitigating the risks of pests and diseases and introducing genes that help plants thrive in their local environments. To do this they are looking for useful traits in traditional cultivars, related species and wild ancestors. Such traits may include tolerance to drought, heat, and poor soils as well as insect and disease resistance. Breeders cross these donor parents with high-yielding elite breeding lines. The resulting new varieties have all the preferred traits of their parents and none of the deficiencies.

The genetic diversity of crops and their wild relatives is held by gene banks. There are thousands of gene banks worldwide, which collect and store seeds from hundreds of thousands of varieties. Breeders and researchers submit seed and tissue of wild and cultivated varieties as well as of lines of new varieties they are trying to breed.

Photo: IRRI

Staff hard at work in the medium-term storage room of the International Rice Genebank at IRRI.

“For years, gene banks were primarily repositories, but with genetics evolving, and its subsequent application in plant breeding growing over the past 10 years, breeders and geneticists are now mining gene banks for wild and exotic species that might have favourable genes for desired traits,” explains Ruaraidh Sackville Hamilton, evolutionary biologist and head of the International Rice Genebank maintained by the International Rice Research Institute (IRRI) at its headquarters in The Philippines.

Sifting through all these gene-bank collections for plants with desired traits is challenging for breeders, even for traits that are easy to select for through visual screening. For example, Ruaraidh says the rice collection held at the International Rice Genebank contains more than 117,000 different types of rice, or accessions.

In recognition of this challenge, the initial rationale of the CGIAR Generation Challenge Programme’s (GCP) genetic stocks activity was to make the diversity in gene banks more easily accessible and practical for the study – and application – of genetic diversity.

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, evolutionary biologist and head of the International Rice Genebank maintained by the International Rice Research Institute (IRRI). 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.

Taking stock of genetic stocks

The first step towards making diversity accessible to breeders was to develop reference sets, representing as much genetic diversity as possible within a small proportion of gene bank accessions, selected through pedigree and molecular marker information.

“Reference sets reduce the number of choices that breeders have to search through, from thousands down to a few hundred,” says Jean Christophe Glaszmann, a plant geneticist at France’s Centre de coopération internationale en recherche agronomique pour le développement (CIRAD; Agricultural Research for Development), who held a managing role at GCP between 2004 and 2010, overseeing much of the reference-set work as GCP’s Subprogramme Leader on Genetic Diversity during GCP’s Phase I.

“A reference set represents the whole diversity found in the collections. Breeders can then use this sample to make crosses with their preferred varieties to try and integrate specific genes from the reference-set lines into those varieties.”

During the first phase of GCP (2004–2008), the Programme focused on identifying and characterising reference sets, each of roughly 300 lines, for banana, barley, cassava, chickpea, coconut, common bean, cowpea, faba bean, finger millet, foxtail millet, groundnut, lentil, maize, pearl millet, pigeonpea, potato, rice, sorghum, sweetpotato, wheat and yam. For most crops phenotyping data – information about physical plant traits – were also being made available for the reference sets, helping researchers to select material of interest for breeding.

Photo: P Kosina/CIMMYT

A trainee at the International Maize and Wheat Improvement Center (CIMMYT) shows off diverse wheat ears, a small sample of the thousands of different lines found in the centre’s gene bank.

A further aspect of the work was the development of data-kits, which included molecular markers used to genotype and verify the sets. These kits allow plant scientists to assess and compare the diversity of their own collections with that of the reference sets, thus facilitating the introduction of new diversity in their prebreeding programmes.

Jean Christophe says the reference sets and data-kits were pivotal to the success of GCP’s molecular-breeding projects as they allowed researchers in different institutes to simultaneously work on the same genetic materials. “The sets served as consistent reference material that everybody collaborating on the project could analyse,” he explains. “Some of these collaborations involved hundreds of researchers, particularly those projects seeking to map genomes and identify genes.”

During the second phase of GCP (2009–2014), the reference sets for GCP’s Phase II target crops (cassava, chickpea, common bean, cowpea, groundnut, maize, rice, sorghum and wheat) were thoroughly phenotyped under different environments, including biotic and abiotic stresses. Jean Christophe says this work helped to identify new alleles (alternative forms of a gene or genetic locus) associated with desired traits that could be used for breeding purposes. Reference sets have been used successfully to identify and use new plant material in breeding programmes to improve various traits, particularly disease resistance and even more complex traits such as drought tolerance in cassava, chickpea, cowpea, maize, sorghum and wheat.

Broadening groundnut’s genetic base to prevent disease

Photo: V Meadu/CCAFS

A farmer in Senegal shows off her groundnut crop, almost ripe for harvest.

Another objective of GCP’s genetic stocks activity was to create new diversity within domesticated cultivated crops that have narrow genetic diversity, such as groundnut.

“The groundnuts we grow today are not too dissimilar to the ones that were first created naturally five to six thousand years ago,” says David Bertioli, a plant geneticist at the University of Brasília, Brazil. “This means that they are genetically very similar and have a narrow genetic base – the narrowest of any cultivated crop.”

This genetic similarity means that all cultivated groundnuts are very susceptible to diseases, particularly leaf spot, requiring expensive agrochemicals, especially fungicides. Without agrochemicals, which smallholder farmers in Africa and Asia often cannot afford, yields can be very low.

David says groundnut breeders always recognised the need to increase diversity, but because cultivated groundnuts have had a narrow base for so long, they became radically different from their wild relatives, making it very difficult to successfully cross wild species with cultivated species.

New genetic diversity is created through recombination, that is, through crossing contrasting varieties to create novel lines. Researchers can study these recombinants to identify genes associated with desired traits or use them in further crosses to develop new varieties.

“One of our first jobs was to make wild-species recombinants to trace out the relatedness of the wild-species genomes,” says David. “Once we could see the relatedness, we could see which wild species we could cross with cultivated lines. We had to do a lot of these crosses, but we eventually started to broaden the genetic diversity of the cultivated lines.”

David says this painstaking work, carried out under GCP, also formed the platform for sequencing the groundnut genome for the first time.

“That gave us an even greater understanding of the genetic structure, which is laying the groundwork for new varieties with traits such as added disease resistance and drought tolerance,” says David.

An additional key outcome of the groundnut aspect of the Legumes Research Initiative was developing ‘wild × domesticated’ synthetic lines, which are being crossed with domesticated groundnut varieties in Malawi, Niger, Senegal and Tanzania to introduce higher drought tolerance.

Photo: C Schubert/CCAFS

Like many areas of Africa struck by climate change, this village in Tanzania is suffering the effects of drought, with temperature increases and increasingly unpredictable rainfall.

Genetic gain by exploiting genetic stocks

The genetic stocks activity has generated a large and diverse array of resources across GCP’s target crops, not just for groundnut.

Recombinant inbred lines (RILs) incorporating specific traits of interest – particularly drought tolerance – have been developed for cowpea, maize, rice, sorghum and wheat. RILs are stabilised genetic stocks, created over several years by crossing two inbred lines followed by repeated generations of sibling mating to produce inbred lines that are genetically identical. These can then be used to discover and verify the role of particular genes and groups of genes associated with desired traits.

Near-isogenic lines (NILs) are RILs that possess identical genetic codes, except for differences at a few specific genetic loci. This enables researchers to evaluate particular genes and groups of genes that they may want to incorporate into breeding lines, particularly genes that have come from plants that otherwise do not perform well agronomically, such as wild relatives or older varieties. Sorghum NILs incorporating the AltSB locus for aluminium tolerance are being tested in Burkina Faso, Mali and Niger on problematic acid soils.

Multiparent advanced generation intercross (MAGIC) populations are a form of recombinants developed from crossing several parental lines from different genetic origins and, in some cases, exotic backgrounds to maximise the mix of genes from the parental lines in the offspring. MAGIC populations have been developed for chickpea, cowpea, rice and sorghum, and are being developed for common bean. Selected parental lines have been used to combine elite alleles for simple traits such as aluminium tolerance in sorghum and submergence tolerance in rice, as well as for complex traits such as drought or heat tolerance.

The further evaluation and use of the genetic stocks stemming from GCP-supported projects, as well as the generation of new genetic stocks, will continue beyond GCP through CGIAR’s Research Programs as well as through those institutes and national breeding programmes associated with GCP. There will be a continuing and evolving need to identify new genes associated with desired traits to improve cultivated germplasm.

Photo: K Zaw/Bioversity International

Transplanting rice plants in Myanmar.

Sustaining genetic stocks into the future

Sustainability of genetic stocks has always been an issue, as stocks are generally not managed in a centralised way but are left under the direct responsibility of the scientists who developed them. These resources have therefore usually been handled in a highly ad hoc manner.

Because of high staff turnover in CGIAR Centers and breeding programmes in developing countries, and also because their management is neither centralised nor coordinated, these resources are also often lost as staff move from one organisation to another.

Although different genetic resources require different management protocols and storage timelines, the idea that gene bank curators take on the management of genetic stocks was proposed several years ago. For Centers such as IRRI, this is already a reality – for at least some of the genetic resources developed.

However, with the growing popularity of tapping into the rich diversity in gene banks that GCP’s genetic stocks activity has helped drive, gene bank supervisors such as Ruaraidh Sackville Hamilton are concerned about how genetic stocks will be sustained.

“The more popular molecular breeding and genetic stock become, the more funds we need to help us curate and disseminate them,” says Ruaraidh. He proposes to recover costs for managing genetic resources through a chargeback system on a two-tier scale, with non-profit organisations receiving stock at lower costs than commercial organisations. “Such a system would be sustainable and reduce the burden on gene bank institutes,” he says.

Still, the costs are of concern to institutes, particularly CGIAR Centers, which maintain most of the world’s plant crop gene banks.

CGIAR, a global partnership that unites 15 research Centres, including IRRI, is engaged in research for a food-secure future. CGIAR also created GCP. “CGIAR’s main priority is to conserve genetic resources for all humankind,” says Dave Hoisington, Senior Research Scientist and Program Director at the University of Georgia in the US. He was formerly Director of Research at the International Crops Research Institute for the Semi-Arid Tropics (ICRISAT) and Director of the Genetic Resources Program and of the Applied Biotechnology Center at the International Maize and Wheat Improvement Center (CIMMYT) (both CGIAR Centers) and Chair of the GCP Consortium Committee.

“In both of the CGIAR Centers I worked in,” says Dave, “we always maintained the position that if the Center were to shut down, the last thing we’d do would be to turn out the lights of the gene bank. Even when we had funding cuts, we would never cut the budget for the gene bank.”

Photo: X Fonseca/CIMMYT

At work in the maize active collection in the gene bank at CIMMYT, which keeps maize and wheat diversity in trust for the world.

New programme to fund crop diversity

To alleviate some of the funding burden on CGIAR Centers and free up more money to use in research and development, CGIAR created a new CGIAR Research Program for Managing and Sustaining Crop Collections. The comprehensive five-year programme is managed by the Crop Trust (formerly Global Crop Diversity Trust).

“The Trust is a financial mechanism to raise an endowment, to ensure the conservation and availability of crop diversity,” says Charlotte Lusty, Genebank Programmes Coordinator at the Global Crop Diversity Trust. “The new programme is an extension of the Trust’s work. We aim to raise a USD 500 million endowment by 2016. The interest from this will be divided between the CGIAR Centers to cover all their long-term conservation operations.”

The new programme is also reviewing how gene banks within CGIAR are being managed, with a view to developing a quality management system, which it hopes will make gene banks run more efficiently. Charlotte says it is also encouraging stronger gene banks, such as IRRI and CIMMYT, to lend their expertise and experience to smaller gene banks so they can meet and build on their management quality.

Dave Hoisington believes that the new programme will provide CGIAR’s gene banks with greater capacity and make them even more attractive for researchers wanting to make use of their rich diversity.

Photo: IRRI

A wide diversity of rice seed from the collection of the International Rice Genebank at IRRI.

Looking forward 30 years

Tapping into new diversity was really at the heart of GCP, and was a major, if not the primary, rationale for its establishment. Over its 10-year lifespan, has invested almost USD 28 million, or 18 percent of its budget, in developing genetic stocks, both reference sets and recombinants, for over 20 different crops.

Although these products don’t directly benefit farmers, they do indirectly help by significantly increasing breeding efficiency.

“All this research is fairly new and I am amazed, as a geneticist and plant breeder, by how far we’ve come since GCP started in 2004,” says David Bertioli.

“What we’ve been able to do in groundnut – that is, broaden the genetic base – hasn’t occurred naturally or through conventional breeding for thousands of years. And we’ve been able to do it in less than ten years.”

David recognises that the true value of the research will only be realised when new disease-resistant varieties are available for farmers to grow, which may be in five to seven years. “Only then will we be able to look back and consider the worth of all the hard work and cooperation that went into developing these precious varieties.”

GCP’s genetic stock activities have generated a large and diverse array of resources. These resources lay the foundation for further genetic stock development and will aid in researchers’ quests to tap into genetic diversity well into the future.

More links

Jun 162015
 
Ripening barley.

Ripening barley.

Barley is thought to have been one of the first crops ever cultivated by humankind. This is largely because it is a tough plant able to withstand dry and salty conditions. Its fortitude is especially important for the small land-holders living on the fringes of deserts in West Asia and North Africa, where it is “the last crop grown before the desert,” says Dr Michael Baum, who led barley research for the CGIAR Generation Challenge Programme (GCP).

Michael, who is Director of the Biodiversity and Integrated Gene Management Programme at the International Center for Agricultural Research in the Dry Areas (ICARDA), says one of the GCP’s first tasks was to find where the useful genes were in wild barley.

“Looking at wild barley is especially important for low-input agriculture, such as is found in developing countries,” he says. “Wild barley grows in, and is very adapted to, the harsh conditions at the edge of the deserts in the Fertile Crescent of West Asia: Iraq, Syria, Jordan and Turkey.”

In some regions, wild barley produces an even higher yield of grain when there is a drought. And this was the kind of useful trait that GCP researchers were looking for in their work on barley during the first phase of GCP, when the internationally funded Programme set out to enhance genetic stocks and plant-breeding skills that will help developing nations cope with increasingly extreme drought conditions.

Signs of barley being domesticated and grown for human use in the Fertile Crescent date back to more than 8,000 BCE. It was a staple cereal of ancient Egypt, where it was used to make bread and beer.  The Fertile Crescent is a crescent-shaped region containing comparatively moist and fertile land within otherwise arid and semiarid West Asia and the Nile Valley and Nile Delta of Northeast Africa. The modern-day countries with significant territory within the Crescent are Cyprus, Egypt, Iraq, Israel, Jordan, Kuwait, Lebanon and Syria; it also includes the southeastern fringe of Turkey and the western fringes of Iran.  Today barley is an important crop for many of these countries, and while production in many other parts of the world is declining it is increasing in this region. Worldwide, barley is grown in more than 100 countries, yielding more than 120 million tonnes a year for food, livestock feed and beer production. This makes it the world’s fourth most important cereal crop, after maize, rice and wheat.

Barley a ‘chosen one’ for research

Photo: Peter Haden/Flickr (Creative Commons)

Preparing barley in Ethiopia.

During its first five years, GCP chose barley as one of its focus crops as advances had already been made in understanding its genetic makeup and in using new molecular plant-breeding technologies to find and incorporate useful genes into barley varieties.

“At the same time, we needed to find the genes or characteristics we did not want in cultivated barley so we could avoid these traits,” says Michael. “This includes the way wild barley disperses its seed when its brittle spikes shatter. Domesticated barley has non-shattering spikes, making it much easier to harvest.”

Resource-poor farmers mostly grow barley in poor environments, where yields of key crops are chronically low, and crop failures are common. Resilient, high-yielding varieties could make a big difference to livelihoods.

Farmers in Central and West Asia and North Africa (CWANA) plant more than five million hectares of barley each year, where it is largely used as feed for the sheep and goats that are the main source of meat, milk and milk products for rural populations. In these environments, barley grain is harvested only two to three times over a five-year period. In years when it is too dry, sheep are sent into the barley field to graze on the straw.

Barley grain is used as animal feed, malt and human food. Barley straw is used as animal feed, for animal bedding and for roofing huts. In many developing countries, livestock graze on the stubble after barley is harvested. Barley is also used for green grazing or is cut before maturity and either directly fed to animals or used for silage. In the highlands of Tibet, Nepal, Ethiopia, Eritrea, in the Andean countries and in North Africa, barley is also an important food source.

Barley-based livestock system on marginal drylands in Morocco.

Barley-based livestock system on marginal drylands in Morocco.

Finding the clues to help breeders select barley’s best DNA

Photo: Dave Shea/Flickr (Creative Commons)

Malted barley.

The quest for better barley varieties – those that yield more, have more protein, can resist pests and diseases and can tolerate drought – means understanding what genes for what characteristics are available to plant breeders.

With 2,692 different barley accessions (or genetically different types of barley) in the ICARDA collection, from 84 different countries, this is no mean feat. GCP-supported researchers selected seed from 1,000 of the most promising accessions and planted single plants, whose seed was then ‘fingerprinted’, or genotyped, according to its DNA composition.

“From this, we selected 300 different barley lines that represented 90 percent of all the different characteristics of barley,” says Michael.

“This [reference set] is really good for someone new to barley. By looking at 300 lines they are seeing the diversity of almost 3,000 lines without any duplication,” he says. “This is much better and quicker for a plant breeder.”

The reference set of 300 barley lines is now available to plant breeders through the ICARDA gene bank.

Morocco researchers use GCP barley reference set to improve food security In Morocco, barley is the second most important cereal after wheat. Farmers produce about 1.3 million tonnes a year from a cultivated area of almost 1.9 million hectares. In this North African country, barley is used as food as well as for animal feed. It plays an important role in food security, as the per capita barley consumption is the highest in the world. However, production is constrained by diseases, pests, and stresses such as drought, and climate change has further aggravated the problem. Morocco imports cereals to meet its domestic demand.  Moroccan varieties of barley have a narrow genetic base, making it difficult to breed better varieties. In this context, the GCP barley reference set was introduced to Morocco from ICARDA and used in the breeding programme. “This has helped my country to develop new varieties,” says Fouad Abbad Andaloussi, Head of the Plant Protection Department at L'Institut National De La Recherche Agronomique (INRA; National Institute for Agricultural Research). “GCP has also greatly enhanced my personal scientific contacts and helped me to explore new developments in plant genetics and biotechnology.”

Photo: ICARDA

Barley growing on experimental fields in Morocco.

Checking out the effects of the environment on gene expression

Photo: World Bank Photo Collection

Harvesting barley in Nepal.

It’s not enough to discover what genes are present in different varieties of barley. It’s also important to understand how these genes express themselves in terms of barley’s yield, quality (especially protein content) and adaptation to stresses such as drought when grown in different environments.

To make this happen, GCP improved collaboration across research centres. This increased the probability of relatively quick advances in identifying new traits and opportunities to improve barley varieties for the poorer farmers of CWANA.

GCP funded a collaborative project between ICARDA and researchers in Australia (the University of Adelaide and the Australian Centre for Plant Functional Genomics), Italy (l’Università degli Studi di Udine) and Syria (Tishreen University) to apply a new method, analysing allele-specific expression (ASE), to understand how genes express themselves in barley, using experimental hybrid plants (cultivated plants crossed with wild barley plants). Over three years, the collaboration tested 30 genes and 10 gene-cross combinations and found that there were changes in genetic expression when plants were grown in drought conditions.

“This is a project we could not have done without the partners in the GCP collaboration,” says Michael. “We gained important insights into how genes are regulated and how gene expression changes under different environmental conditions, such as drought, or during growth stages, such as early plant development or grain filling. We published our results in a high-impact journal [The Plant Journal (2009) 59(1):14–26], which was a great outcome for a project with such a limited timespan.”

This project was designed not so much for the practical plant breeder, but for those using molecular-breeding technologies where it is important to understand that there is a change in the expression of genes over the lifetime of a plant. “This affects the selection of genes for breeding programmes,” says Michael.

Barley: Food of gladiators Barley contains about 75 percent carbohydrate, 9 percent protein and 2 percent fat. Barley grain is rich in zinc (up to 50 ppm), iron (up to 60 ppm) and soluble fibres and has a higher content of Vitamins A and E than other major cereals. Barley has been documented as a high-energy food since the Roman times, when the gladiators were called ‘hordearii’, meaning barley men or barley eaters, because they were fed a barley diet before going to an arena to fight. Some varieties of barley are also remarkably high in protein. For example, some Ethiopian varieties have up to 18 percent protein.

Photo: Peter Haden/Flickr (Creative Commons)

Preparing barley in Ethiopia.

Making the most of wild barley

Photo: Rahel Jaskow/Flickr (Creative Commons)

Wild barley in flower.

Once some of the fundamental research into barley’s building blocks had been done, GCP revisited the potential of wild barley, with the aim to identify specific DNA that increased or decreased drought tolerance.

“Whenever you can’t find the characteristics you are looking for in a cultivated crop, you go back to look again at the wild varieties,” says Michael.

Once again, a collaborative effort – this time between ICARDA, the Scottish Crop Research Institute (since renamed to the James Hutton Institute), the University of California, Riverside, the University of Oregon and Chile’s Instituto de Investigaciones Agropecuarias (INIA; Agricultural Research Institute) – was the key to success.

Joanne Russell from the James Hutton Institute says success came when “we combined the power of genomics with a unique population of 140 barley lines to identify segments of the donor genome that confer drought tolerance”.

The barley lines were composed of an advanced elite genetic background combined with introduced segments of DNA from wild barley that came from the Fertile Crescent.

“We were successful in identifying parts of the DNA from hybrid plants that confer a significant increase in yield under drought,” says Joanne.

Leader of this GCP project from the James Hutton Institute, Professor Robbie Waugh, adds that GCP provided a unique opportunity for their laboratory to interact with international colleagues on a project focussed on improving the plight of some of the world’s poorest subsistence farmers.

“The genetic technologies we had developed prior to the GCP project starting were, at the time, state of the art – even in the more developed world,” says Robbie. “Our ability to then apply these technologies to wild barley genetic material from ICARDA and to varieties derived from wild × cultivated crosses allowed us to learn a lot about patterns of genetic and phenotypic variation in the wider barley gene pool.

“Indeed, we are still working on one of the genetic populations of barley that we studied in the GCP program, now using sophisticated phenotyping tools and approaches to explore how genes in defined segments of the wild barley genome help provide yield stability under drought conditions through architectural variation in the root system.”

Photo: Richard Weil/Flickr (Creative Commons)

Women harvesting barley in India.

GCP builds genetic resources through ongoing collaboration

Photo: Diana Prichard/ONE.org/Flickr (Creative Commons)

Barley in rural Ethiopia.

For Michael, one of the most important outcomes of the GCP work was the ability to meet and work with researchers from other centres across the world.

“Before GCP, I had only visited two other CGIAR centres,” he says. “GCP was the first attempt to develop a programme across the CGIAR centres and to work on a specific topic, which was genetic resources. I would give GCP high marks for stimulating this cross-centre cooperation, particularly through their annual GCP meeting.”

And when the decision came to end barley research after the first phase of GCP, Michael found that he missed the GCP meetings: “I would have found it useful if I could have continued to attend the annual meetings,” he says. “These were much more important to me than getting the project funding out of GCP.”

Despite this and despite dealing with the challenge that some countries, such as China, were unable to provide the barley germplasm (samples of materials) that they initially promised, Michael has continued his relationships with some of the people he first met through GCP. “I’m still collaborating with China through a continuous bilateral effort on barley. Ten years later, the collaborations are still ongoing. Often when a project finishes, the collaboration finishes, but we are still continuing our collaboration on barley.”

Most importantly, Michael believes the GCP-supported and -funded collaborations brought a new approach to providing plant genetic resources to breeders. “The reference sets we assembled for barley and other crops provided a new way to look at large germplasm collections,” he says.

“This was one aim of GCP: about how to have a more rational look at germplasm collections. Now plant breeders don’t have to ask for five to ten thousand accessions of a crop, and then spend several years on evaluation.

“Now they have a higher chance of finding the genetic characteristics they want more quickly from the much smaller reference collection.”

And although the reference-set approach has been further refined since GCP’s first phase of research concluded, Michael believes it builds on what GCP started through its collaborative teams, with barley being just one example.

“GCP helped make it all happen,” he says.

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

Photo: Oleksii Leonov/Flickr (Creative Commons)

Field of barley.

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.”

More links

Photo: P Casier/CGIAR

Kenyan farmer Emily Marigu with her sweetpotatoes.

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).

More links