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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.

Jan 302015
 

“Little had been done to advance the genetic diversity of lentils.” This was the picture back in 2005, recalls Aladdin Hamwieh, a scientist at the International Center for Agricultural Research in the Dry Areas (ICARDA) based in Lebanon.

“Lentil has a narrow genetic base, meaning not too many varieties are used in production,” he explains.

Photo: ICARDA

A small sample of the lentil diversity available in the ICARDA gene bank.

It was on this premise that Aladdin joined a three-year global effort to capture and understand the genetic diversity of the world’s lentil varieties – a protein-rich crop that plays an integral part in the lives of many people in Central and West Asia and North Africa (CWANA), South Asia and North America.

He was funded by the CGIAR Generation Challenge Programme (GCP) to develop a refined set of genetic reference materials for lentils so that plant breeders across the globe could access the best gene pool available to be able to improve food security in developing countries.

“Essentially, the genetic make-up of lentil was repeatedly filtered until 15 percent of ICARDA’s gene bank was collected,” says Aladdin.

ICARDA has the largest collection of lentil genes in the world. Some work had been done on improving the genetics of lentils to withstand harsh, dry conditions. But it was not enough to prepare for the challenge the world is now facing – feeding almost 10 billion people by 2050 and climate conditions that mean longer dry periods and more erratic rainfall.

ICARDA has a global mandate for research on lentil improvement. As such, ICARDA houses the world’s collection of lentils, held in trust as a global public good. It includes 8,789 different types of seed of cultivated lentils from 70 countries, 1,146 breeding lines and 574 new seed samples from 4 wild lentil species representing 23 countries. From this, a collection of 1,000 plants was identified for use as GCP reference materials, consisting of traditional farmer varieties, wild relatives and elite varieties and cultivars. Individual plants of each were planted in 2005 so that seed could be collected at the end of the growing season.

The reference set captures the existing genetic diversity of lentils and makes it easier for scientists to search for genes that can help overcome the challenges to lentil production. It consists of about 150 accessions, or 15 per cent of the global collection studied (see box).

Creating the reference set immediately helped researchers to understand more about lentils. “The major outcome was that different gene pools were identified where accessions from Europe and America were clearly separated from Asia and Africa,” Aladdin says. “Accessions from India, Afghanistan and Pakistan were also separated from accessions from the Middle East and North Africa.”

A common resource for lentil breeders

International cooperation and knowledge sharing are hallmarks of GCP, with one of the Programme’s key goals being to facilitate collaboration between scientists from across the globe in breeding new varieties of crops that can not only tolerate drought, but also resist diseases and tolerate poor soils. Ashutosh Sarker, a former lentil breeder and currently Coordinator and Food Legume Breeder for ICARDA’s South Asia and China Regional Program, says production challenges for lentils vary from country to country. While demand is rising globally, he says, some developing countries are having trouble meeting their own need for this staple food.

Photo: P Casier/CGIAR

A woman farmer with lentils in Bihar, India.

This was where the GCP work came in; its purpose, according to Aladdin, was to “develop a diverse reference set that is small and easy to handle. This way, it can be sent around the world for scientists to simultaneously screen for desirable or undesirable traits. This has important implications for developing countries.”

The reference collection serves as a common resource for all lentil breeders interested in the same crop.

“These materials can be accessed to achieve farming goals – to produce tough plants suitable for local environments. In doing this, farmers have a greater likelihood of success, which ultimately improves the wider population’s food security.”

When Aladdin’s team studied the reference collection, they were able to identify favourable genes.

“This enables us to look at the genes of plants and highlight those traits that best suit certain environments,” he says, “and then breed plants to be better adapted.”

Lentils – with a protein content ranging from 22 to 35 percent – are an important source of dietary protein in both human and animal diets, second only to soya beans as a source of usable protein. Lentils are currently grown on 3.8 million hectares worldwide, with a total annual production of over 3.5 million tonnes. The major producers of lentils are countries the South Asia and CWANA regions, and Canada, Australia and the USA. Productivity is low in developing countries, largely because the crop is grown on marginal lands in semiarid environments, without irrigation, weeding or pest control.

Diversity is key to searching for valuable breeding traits

Shiv Kumar Agrawal, who joined ICARDA in 2009, uses the reference set developed for GCP to identify and create markers for drought-tolerant and early-maturing traits for key lentil-producing countries, including Bangladesh, Ethiopia and India.

“Developing more markers will help mitigate lentil’s barriers to production,” says Shiv, pointing to climate change and rising temperatures in production zones as adversely affecting lentil yields.

Markers are like genetic ‘tags’ that indicate which plants or seeds have particular genes, so markers related to relevant genes – for traits such as heat tolerance, for example – can help breeders choose which plant materials to use when developing a new variety.

“Breeding for this should be a priority,” he continues. “Developing heat-tolerant lentil plants would help to expand the area of legume cultivation, stabilise yield in areas prone to heat stress and mitigate impacts of global climate change in the future.”

This is the same for other traits, he says, which would improve food security in developing countries: “Developing extra-early breeds of lentils has great scope in diversifying cropping methods and gives more flexibility for farmers.”

Photo: T Wolday/Bioversity International

Farmers in Ethiopia winnow orange lentils.

Karthika Rajendran, a postdoctoral student working with Shiv at ICARDA, uses both conventional and molecular-breeding approaches to develop heat-tolerant lentil cultivars that mature early. The products of GCP, she says, are “helpful to identify the source of genetic diversity and molecular markers for the traits identified under each research targets.”

Like Shiv, Karthika stresses the value of heat-tolerant varieties for heat-stressed areas and in reducing the impacts of climate change, and adds that improving other traits alongside also has significant impacts: “The development of machine-harvestable lentils reduces the production cost, increases the farm profit, reduces the drudgery of women and improves the nutritional and food security of smallholder farmers in developing countries.”

Photo: E Huttner/ACIAR

Farmer Minto with lentils in his field in Bangladesh.

While achieving such lentil varieties may be some way down the track, Shiv and Karthika offer a small glimpse of what the future holds and the promise of making even more from GCP’s genetic reference set than what has been achieved so far.

Preserving genetic resources

Aladdin Hamwieh is also looking to the future: “We don’t know what tomorrow brings, so people need to understand the value of such genetic reference material.”

He reflects on the reality of how civil unrest in developing countries often means local agriculture is disrupted and crops destroyed, which can mean the loss of traditional varieties.

“We could lose interesting genes from these,” says Aladdin. “We must therefore maintain and protect the ICARDA database, because it stores important information that the next generation won’t be able to study in nature.”

Aladdin is adamant that this is important not only for developing countries but for the whole world. “We can’t make genes in future so this one we cannot lose,” he stresses.

A ‘backup’ duplicate copy of ICARDA’s lentil collection is stored in the Arctic Circle at the Svalbard Global Seed Vault.

Groundwork on lentils ‘gave orientation to future breeding efforts’

Although GCP’s genetic research work on lentils came to an end in 2007, scientists all over the world can still access the materials – and are reaping other benefits from GCP’s work too. For example, ICARDA is using GCP’s Integrated Breeding Platform (IBP) – particularly the Breeding Management System (BMS) – for its lentil-breeding programme.

Reflecting GCP’s collaborative spirit, Shiv explains that his team have not only successfully integrated use of BMS within their own programme, but have also included it in regular training programmes for developing country partners.

Karthika says, “We use the BMS to store historical data of crossing blocks and germplasm collections and to create fieldbooks, field maps and labels of yield trials. We use the crossing manager to build up the list of the crossing blocks, and the breeding manager to maintain the pedigree of the breeding programme.”

She explains that within the BMS, “the breeding view demonstrated a great potential to analyse the phenotypic and genotypic data for single and multienvironmental conditions,” and notes that “the Molecular Breeding Design Tool would be useful in the process of marker-assisted selection.”

ICARDA plans to implement the BMS to develop fieldbooks for Lentil International Elite Nurseries, using the IBFieldbook tool, and to distribute the books to developing country partners for data collection.

“Once the database is centralised, it will facilitate rapid access to breeding material and easy sharing of knowledge and technology to the developing country partners,” says Karthika.

Such ongoing advances in breeding technologies since the outset of GCP mean the refining process can continue.

“We should not stop,” says Aladdin, encouraging other lentil breeders and researchers to continue their work.

Photo: Bill & Melinda Gates Foundation

A female farmer in India helps to harvest lentils by sifting them after fellow workers have beaten the stalks to remove the seeds from their pods.