Jan 072015
 
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Beyond chickpeas to embrace beans, chickpeas, groundnuts and pigeonpeas

Paul_w2As a scientist who comes from the dessicated drylands of the unforgiving Kerio Valley, where severe drought can mean loss of life through loss of food and animals, what comes first is food security… I could start to give something back to the community… It’s been a dream finally coming true.” – Paul Kimurto, Senior Lecturer and Professor in Crop Physiology and Breeding, Egerton University, Kenya

As a son of peasant farmers growing up in a humble home in the Rift Valley of Kenya, agriculture was, for Paul Kimurto (pictured above), not merely a vocation but a way of life: “Coming from a pastoral community, I used to take care of the cattle and other animals for my father. In my community livestock is key, as is farming of food crops such as maize, beans and finger millet.”

Covering some six kilometres each day by foot to bolster this invaluable home education with rural school, an affiliation and ever-blossoming passion for agriculture soon led him to Kenya’s Egerton University.

There, Paul excelled throughout his undergraduate course in Agricultural Sciences, and was thus hand-picked by his professors to proceed to a Master’s degree in Crop Sciences at the self-same university, before going on to obtain a German Academic Exchange Service (DAAD) scholarship to undertake a ‘sandwich’ PhD in Plant Physiology and Crop Breeding at Egerton University and the Leibniz Institute for AgriculturalEngineering (ATB) in Berlin, Germany.

… what comes first is food security… offering alternative drought-tolerant crops… is a dream finally coming true!…  GCP turned out to be one of the best and biggest relationships and collaborations we’ve had.”

Local action, global interaction
With his freshly minted PhD, Paul returned to Egerton’s faculty staff and steadily climbed the ranks to his current position as Professor and Senior Lecturer in Crop Physiology and Breeding at Egerton’s Crop Sciences Department. Yet for Paul, motivating this professional ascent throughout has been one fundamental factor:  “As a scientist who comes from a dryland area of Kerio valley, where severe drought can mean loss of food and animals, what comes first is food security,” Paul explains. “Throughout the course of my time at Egerton, as I began to understand how to develop and evaluate core crop varieties, I could start to give something back to the community, by offering alternative drought-tolerant crops like chickpeas, pigeonpeas, groundnuts and finger millet that provide farmers and their families with food security. It’s been a dream finally coming true.”

And thus one of academia’s true young-guns was forged: with an insatiable thirst for moving his discipline forward by seeking out innovative solutions to real problems on the ground, Paul focused on casting his net wide and enhancing manpower through effective collaborations, having already established fruitful working relationships with the International Maize and Wheat Improvement Center (CIMMYT), the (then) Kenya Agricultural Research Institute (KARI) and the International Crops Research Institute for the Semi-Arid Tropics (ICRISAT) in earlier collaborative projects on dryland crops in Kenya. It was this strategy that paved the way towards teaming up with GCP, when, in 2008, Paul and his team were commissioned to lead the chickpea work in Kenya for the GCP Tropical Legumes I project (TLI), with local efforts being supported by colleagues at ICRISAT, and friends down the road at KARI undertaking the bean work of the project. Climbing aboard the GCP ship, Paul reveals, was a move worth making: “Our initial engagement with GCP started out as a small idea, but in fact, GCP turned out to be one of the best and biggest relationships and collaborations we’ve had.”

…GCP is people-oriented, and people-driven” 

Power to the people!
The success behind this happy marriage, Paul believes, is really quite simple: “The big difference with GCP is that it is people-oriented, and people-driven,” Paul observes, continuing: “GCP is building individuals: people with ideas become equipped to develop professionally.” Paul elaborates further: “I wasn’t very good at molecular breeding before, but now, my colleagues and I have been trained in molecular tools, genotyping, data management, and in the application of molecular tools in the improvement of chickpeas through GCP’s Integrated Breeding Multiyear Course. This has opened up opportunities for our local chickpea research community and beyond, which, without GCP’s support, would not have been possible for us as a developing-country institution.”

Inspecting maturity, Koibatek FTC, Bomet_R Mulwa_Sep'12_w

Inspecting pod maturity with farmers at Koibatek Farmers Training Centre in Eldama Ravine Division, Baringo County, Kenya, in September 2012. Paul is on the extreme right.

Passionate about his teaching and research work, it’s a journey of discovery Paul is excited to have shares with others: “My co-workers and PhD students have all benefitted. Technicians have been trained abroad. All my colleagues have a story to tell,” he says. And whilst these stories may range from examples of access to training, infrastructure or genomic resources, the common thread throughout is one of self-empowerment and the new-found ability to move forward as a team: “Thanks to our involvement with the GCP’s Genotyping Support Service, we now know how to send plant DNA to the some of the world’s best labs and to analyse the results, as well as to plan for the costs. With training in how to prepare the fields, and infrastructure such as irrigation systems and resources such as tablets, which help us to take data in the field more precisely, we are now generating accurate research results leading to high-quality data.”

The links we’ve established have been tremendous, and we think many of them should be long-lasting too: even without GCP

Teamwork, international connections and science with a strong sense of mission
Teaming up with other like-minded colleagues from crème de la crème institutions worldwide has also been vital, he explains: “The links we’ve established have been tremendous, and we think many of them should be long-lasting too: even without GCP, we should be able to sustain collaboration with KBioscience [now LGC Genomics] or ICRISAT for example, for genotyping or analysing our data.” He holds similar views towards GCP’s Integrated Breeding Platform (IBP): “IBP is one of the ideas which we think, even after GCP’s exit in December 2014, will continue to support our breeding programmes. My colleagues and I consult IBP regularly for a range of aspects, from markers to protocols to germplasm and the helpdesk, as well as for contacts and content available via the IBP Communities of Practice.” Paul’s colleagues are Richard Mulwa, Alice Kosgei, Serah Songok, Moses Oyier, Paul Korir, Bernard Towett, Nancy Njogu and Lilian Samoei. Paul continues: “We’ve also been encouraging our regional partners to register on IBP – I believe colleagues across Eastern and Central Africa could benefit from this one-stop shop.”

Yet whilst talking animatedly about the greater sophistication and accuracy in his work granted as a result of new infrastructure and the wealth of molecular tools and techniques now available to him and his team, at no point do Paul’s attentions stray from the all-important bigger picture of food security and sustainable livelihoods for his local community: “When we started in 2008, chickpeas were known as a minor crop, with little economic value, and in the unfavoured cluster termed ‘orphan crops’ in research. Since intensifying our work on the crop through TLI, we have gradually seen chickpeas become, thanks to their relative resilience against drought, an important rotational crop after maize and wheat during the short rains in dry highlands of Rift valley and also in the harsh environments of the Kerio Valley and swathes of Eastern Kenya.”

This GCP-funded weather station is at Koibatek Farmers Training Centre, Longisa Division, Bomet County.

This GCP-funded weather station is at Koibatek Farmers Training Centre.

Having such a back-up in place can prove a vital lifeline to farmers, Paul explains, particularly during moments of crisis, citing the 2011–2012 outbreak of the maize lethal necrosis (MLN) disease which wiped out all the maize throughout Kenya’s  Bomet County, where Paul, Richard, Bernard and their team had been working on the chickpea reference set. Those farmers who had planted chickpeas – Paul recalls Toroto and Absalom as two such fortunate souls – were food-secure. Moreover, GCP support for infrastructure such as a weather station have helped farmers in Koibatek County to predict weather patterns and anticipate rainfall, whilst an irrigation system in the area is being used by the Kenyan Ministry of Agriculture to develop improved seed varieties and pasture for farmers.

The science behind the scenes and the resultant products are of course not to be underestimated: in collaboration with ICRISAT, Paul and his team released four drought-resistant chickpea varieties in Kenya in 2012, with the self-same collaboration leading to the integration of at least four varieties of the crop using marker-assisted backcrossing, one of which is in the final stages and soon to be released for field testing. With GCP having contributed to the recent sequencing of the chickpea genome, Paul and his colleagues are now looking to up their game by possibly moving into work on biotic stresses in the crop such as diseases, an ambitious step which Paul feels confident can be realised through effective collaboration, with potential contenders for the mission including ICRISAT (for molecular markers), Ethiopia and Spain (for germplasm) and researchers at the International Center for Agricultural Research in the Dry Areas (ICARDA) for germplasm. Paul first established contact with all of these partners during GCP meetings.

By coming together, pooling skills from biotechnology, agronomy, breeding, statistics and other disciplines, we are stronger as a unit and better equipped to offer solutions to African agriculture and to the current challenges we face.”

Links that flower, a roving eye, and the heat is on!
In the meantime, the fruits of other links established since joining the GCP family are already starting to blossom. For example, TLI products such as certified seeds of chickpea varieties being released in Kenya – and in particular the yet-to-be-released marker-assisted breeding chickpea lines which are currently under evaluation – caught the eye of George Birigwa, Senior Programme Officer at the Program for Africa’s Seed Systems (PASS) initiative of the Alliance for a Green Revolution in Africa (AGRA), which is now supporting the work being undertaken by Paul and his team through the Egerton Seed Unit and Variety Development Centre (of which Paul is currently Director) at the Agro-Based Science Park.

Yet whilst Paul’s love affair with chickpeas has evidently been going from strength to strength, he has also enjoyed a healthy courtship with research in other legumes: by engaging in a Pan-African Bean Research Alliance (PABRA) bean project coordinated by the International Center for Tropical Agriculture (CIAT), Paul and his team were able to release and commercialise three bean varieties which are currently in farmers’ fields in Kenya.

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Paul (left) in the field. The crop is chickpeas of course!

With so many pots on the boil, the heat is certainly on in Paul’s research kitchen, yet he continues to navigate such daily challenges with characteristic aplomb. As a proven leader of change in his community and a ‘ can-do, make-it-happen’ kind of guy, he is driving research forward to ensure that both his school and discipline remain fresh and relevant – and he’s taking his colleagues, students and local community along with him every step of  the way.

Indeed, rallying the troops for the greater good is an achievement he values dearly: “By coming together, pooling skills from biotechnology, agronomy, breeding, statistics and other disciplines, we are stronger as a unit and better equipped to offer solutions to African agriculture and to the current challenges we face,” he affirms. This is a crusade he has no plans to abandon any time soon, as revealed when quizzed on his future aspirations and career plans: “My aim is to continue nurturing my current achievements, and to work harder to improve my abilities and provide opportunities for my institution, colleagues, students, friends and people within the region.”

With the chickpea research community thriving, resulting in concrete food-security alternatives, we raise a toast to Paul Kimurto and his chickpea champions!

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Jan 282013
 
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Today, Nature Biotechnology published the first-ever draft genome sequence map for a chickpea variety (PDF). The map will help researchers and breeders the world over to – through molecular breeding methods – deliver to growers higher-yielding more resilient varieties of chickpeas. 

Now that we have the rewards in a nutshell, and we choose to chew the chestnut of challenges later in the story, let’s next decipher the ‘Rajeevs’ part in the title: introducing Rajeev K Varshney, our very own Leader of Comparative and Applied Genomics, who also led and coordinated the transnational collaboration that developed this map.

We had the pleasure of talking to the gently-spoken Indian, a week before the release of the paper, asking him to recount how the project began, and the challenges and success they faced along the way. We’ll soon get to what Rajeev had to say, but first, a rapid rewind for backgrounding before Rajeev tells us the rest of the story…

… we have the ‘borders’ done… a good idea of what the picture is, and where the rest of the pieces will fit.”

Rajeev in the lab.

Reality check from the Genomics Gnome of Good News: two is but the twinkling of an eye…
The sequence map of the genotype CDC Frontier – a Canadian kabuli chickpea variety – took about two years to construct.”

No, the time taken is not the challenge since we’re yet to get to that part. In fact, in the world of genomics , two years is fairly fast, compared to, say, the time taken for sequencing other grain genomes such as maize, rice and wheat.

Rajeev attributes this to the interdisciplinary expertise of his team, most of whom are world leaders in their field, and to the enthusiasm and generosity of all partner institutes who funded the collaboration.

And with that background, on to our chat with Rajeev!

Sandwiches in the Sunshine State, and a search starts for the then unattainable holy grail

Q: Is it correct that this project started over sandwiches under a sunny sky in California?
Funnily enough, yes. We had the preliminary discussion during a lunchtime break at the fifth International Congress on Legume Genetics and Genomics back in July 2010. Doug Cook, from the University of California, Davis, and I, organised the meeting for select attendees to discuss the idea.

With daughter, Nanz. Rajeev in ‘Daddy-mode’, a galaxy away from genomic research.

Many researchers at the time had, or were toying with, sequencing parts of the chickpea genome to discover genes that helped plants tolerate salinity, drought, disease, and so on. The idea of mapping the whole genome, however, was thought to be unachievable given the cost and resources required. What Doug and I proposed to the 10-odd senior researchers that day was that we form an alliance to pool together our knowledge, funds and resources.

When we returned to our home institutes, we all approached our institutes or funding agencies in respective countries, to propose they consider funding the collaborative project. To be honest, this was probably the most challenging task of the project, as it often is with other projects, as they had a hard time recognising the benefits. However, we finally got there, and with the help of more than 20 institutes from North and Central America, Asia, Australia and Europe, we have successfully assembled 74 percent of the genome within two years.

Pieces fall into place for mix-and-match combinations

Now, you may say that 74 percent doesn’t equal the whole genome, but it does provide us with a map and pointers we’d never had before. Imagine doing a jigsaw without a picture to guide you – that’s how hard it was for us at the start. Now at least we have the ‘borders’ done, and we have a good idea of what the picture is, and where the rest of the pieces will fit.

Q:Why is mapping the chickpea genome so important?
Having the genome mapped is going to benefit all chickpea breeders, researchers and growers.

Say a conventional breeder wanted to create a new breed of chickpeas with drought tolerance. They would cross a domesticated, high-yielding variety of chickpeas, with a variety that tolerates dry conditions – most likely, lower-yielding – and then grow the progeny in the field. They wait for these progenies to grow, then visually select the best lines and make crosses with these. They keep doing this process over and over again for six to seven years until they’ve generated a new variety with the desired trait.

Different breed, mould and mode

Molecular breeders do it differently: instead of selecting the lines by visual inspection, they select lines based on their genes. This means they can correctly trace whether the progeny has received the genes which help the plant tolerate drought and only grow, test and cross with these plants, almost halving the time it would take through conventional methods.

With the map, researchers will be able to more rapidly identify genes of interest, and work with breeders to select for plants that display the favourable traits of these genes, whether this be for drought tolerance, pest resistance or for any other trait they are interested in.

Q: Good for researchers and breeders, but how is that going to benefit growers though?
Knowing which plant is more tolerant of drought from the start of the breeding process is going to significantly reduce the time it takes for breeders to develop these types of chickpea cultivars. So, growers will have new breeds of higher-yielding more resilient chickpeas available sooner.

Ethiopian farmer, Temegnush, and her chickpea harvest.

Remember also that chickpeas are a very important crop for smallholders in the resource-poor harsh environments of sub-Saharan Africa, India and Southeast Asia. Not only do they grow it for food and to replenish soil nitrogen, they also export to India, the world’s largest consumer of chickpeas. Most of these farmers would be lucky to harvest one tonne per hectare, so any yield advantage means extra income.

This point is particularly relevant for GCP’s goal, which is to improve the livelihoods of such farmers.

Q: This was one of the largest collaborative projects you’ve coordinated in your relatively short career. What was the most challenging aspect?
Short answer is….many!  With it being a collaborative project, bringing together researchers from all around the world, it was always difficult to coordinate suitable times for Skype and phone meetings.

Personally though, my biggest challenge was trying to coordinate so many esteemed researchers. We all had great ideas and we all thought each of our ideas was the right one. I had to resolve all issues amicably and find a solution to move forward.

Luckily I have surrounded myself over the years with some good colleagues to whom I’ve always been able to turn to discuss any problems. Jean-Marcel Ribaut, who is the Director of GCP, was one particular colleague to whom I often turned to for advice, given his experience with coordinating all of GCP’s collaborative interdisciplinary projects. He also helped source much-needed funds and suggested several useful partnerships, which were vital in carrying out the project.

My boss at ICRISAT, William Dar, the Director General, has always been very supportive, and time and again went out of his way to make sure I had the funds, capacity and sanity to keep the project going! I am deeply indebted to him.

The future

Q: How will the research continue?
Researchers and breeders will be able to customise the genome map to fit their particular purposes. Most will be interested in using it to develop molecular markers, which breeders can use to highlight specific genes of interest for molecular breeding. As I mentioned earlier, this could realistically halve the time it takes to breed new varieties from six to10 years to four to five years.

One outcome of the project, which I’m particularly interested in exploring further, relates to chickpea diversity. When we compared the 90 chickpea genomes, we realised that that diversity in the elite varieties was very low, meaning they all had very similar alleles (form of genes).

This has come about because over the years, breeders and growers have continually chosen only a handful of chickpea varieties to continually breed with. This is because these breeds tend to produce higher yields, something which all growers want.

The drawback of this, however, is that if all the popular breeds are too similar, then they could all be susceptible to a particular disease. If this particular disease were to strike, then chickpeas could be wiped out – globally.

So this map will be a valuable tool to use to enhance genetic diversity in the elite gene pool, thus safeguarding the world’s supply of chickpeas.

 

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Jun 302012
 
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Fikre Asnake (pictured)  is a researcher and breeder in both Tropical Legumes I and II projects (TLI and TLII), working at the Ethiopian Institute of Agricultural Research (EIAR).

He has been leading the project activities since 2008. Through the project, EIAR has obtained diverse chickpea germplasm from ICRISAT. This germplasm is undergoing different breeding schemes using marker-assisted recurrent selection (MARS) and marker-assisted backcrossing (MABC) for evaluation.

The germplasm is now in the pre-release testing phase. Some of the work is being done by postgraduate students trained by TLI (two PhDs and 1 MSc). The project is using MABC to introduce drought-resistant traits into proven superior cultivars. “We expect good gains in productivity for drought-prone environments, which will make a huge difference. The varieties we hope to release will increase not only quantity, but also quality,” says Fikre. “We anticipate some of these improved chickpea varieties will be released in the course of Phase II of the TLI project, based on work that began in Phase I.”

Building capacity
Capacity-building is a crucial cornerstone. “In addition to our three postgraduate students, about five or six of our researchers and technicians have been trained in molecular breeding and related areas, mostly at ICRISAT in India ,” reports Fikre. And that is not all: “We have also benefited from infrastructure improvements, including construction of a rainout shelter for our drought trials and coldrooms for seed preservation. A glasshouse will also be built for trials under controlled conditions.”

Fikre further notes, “These facilities and staff development will make us more effective in achieving the objectives we have set in the project. In addition, because the infrastructure is shared with other colleagues not directly involved in the TLI project, it is also an indirect conduit for further cementing synergies and collaboration, even as we already have good synergies with the national programme’s breeding scheme.”

Fikre is keen to see the capacity building translate into a larger critical mass of breeders conversant with molecular breeding, as well as an increase in the information on chickpeas, an area in which students have been extremely instrumental in eriching. “We are all learning a lot from molecular technologies through TLI, and beyond that, how to actually apply these technologies in a breeding programme.”

VIDEO: Fikre discusses capacity-building with other TLI colleagues

What next?
Looking into the future, what are Fikre’s projections and aspirations regarding TLI Phase II? “It is now time to test the drought-tolerant breeding lines already processed and tested through MARS. We will be undertaking this testing over the next two to three years or so, to see what gains have been made towards improving chickpeas.”

This testing will be done through multilocation trials both in research stations as well as on farmers’ fields, and will include a parallel evaluation and validation by colleagues outside the project.

“By the end of TLI Phase II, our goal is to have varieties that will go to farmers’ fields that will make a clearly discernible difference,” concludes Fikre.

VIDEO: Involving farmers in selecting varieties – Fikre and other TLI colleagues

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Jun 302012
 
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“When we first started working on this project in mid-2007, our breeding programme was very weak,” says Paul Kimurto (pictured), Lead Scientist for chickpea research in the Tropical Legumes I (TLI) project, Kenya, and a lecturer in Crop Science at Egerton University.

“We have since accumulated a lot of germplasm, a chickpea reference set, and a mapping population, all of which have greatly boosted our breeding programme. From these, we have been able to select appropriate genotypes, and we obtained 400 breeding lines. None of this would have been directly possible without GCP’s support,” adds Paul. [Editor’s note: A ‘reference set’ is a sub-sample of existing germplasm collections that facilitates and enables access to existing crop diversity for desired traits, such as drought tolerance or resistance to disease or pests]

Due to their hardiness against drought, chickpeas have been steadily gaining popularity in Kenyan drylands – including the dry highlands – where they are grown as a ‘relay’ crop after wheat and maize harvests during the short rains, when the land would otherwise lie fallow. “Chickpeas have therefore increased food security and nutritional status of more than 27,000 households living in Baringo, Koibatek, Kerio Valley and Bomet Districts in Kenya, who frequently face hunger due to frequent crop failure of main staples such as maize and beans owing to climate change,” says Paul.

Chickpea adoption in these areas has increased due to close collaboration between GCP, ICRISAT and Egerton University through funding, training, resources and germplasm facilitated by GCP.

Exposure and capacity building
Through the project, various members of the Egerton research team have benefited from training in Europe, Africa and Asia on wide-ranging aspects of modern breeding, including data management. The learning resources that the team accesses through GCP are also shared widely and used as teaching materials and resources for faculty staff and postgraduate students not directly involved in the project.

“We have also benefitted from physical infrastructure such as a rain-shelter, irrigation system, laboratory equipment and a greenhouse. We didn’t have these, and probably couldn’t have had them, because all these are costly investments. This has greatly improved the efficiency of not only our research, but also our teaching,” says Paul. In addition, three postgraduate students are supported by GCP – two are pursuing PhDs and one a Masters, all using modern molecular breeding methods in their studies.

VIDEO: Paul discusses capacity building in Kenya, alongside other TLI colleagues


Community gains

Besides the university, capacity building has benefited the broader community: agricultural extension staff from the Ministry of Agriculture and from Koibatek Farmers Training Centre (one of the project’s research site), have been trained in various fields. The Centre manager attended a GCP course in Ghana tailored for research station staff (link below), as did an Egerton University technician.

In addition to aiding research trials, the irrigation system and weather station installed at Koibatek help with teaching and producing crop seed and planting materials as well as pasture for the community, since the Centre has a mandate to provide high-quality seed and livestock breeds to the community.

According to Beatrice Komen, a farmer in Koibatek, the irrigation system “has enabled the Agricultural Training Centre supply us with high-quality pasture and crop seeds for planting during the right time because Egerton University uses it to produce sufficient seed without having to rely on seasonal conditions.”

Paul adds, “The automated weather station is a first in the region.” The weather station also feeds regional data into the national meteorological database and is used for teaching by secondary schools in the community.

Going further, faster
Paul observes “With the direct funding we obtain through the project, we are able to expand into other areas of dryland research such as soil science and nitrogen fixation for chickpeas. Our efficiency has also increased: with the greenhouse and rainout shelter, we can now rapidly obtain generation crosses. And the irrigation system means we can now do off-season trials without having to wait for seasonal changes.”

“We have learnt a lot through our involvement with the Programme, including outsourcing of genotyping services which GCP fully supports, the advanced tools and wide range of services offered by the Integrated Breeding Platform for both breeding and data management,” says Paul. “We have also received digital tablet for electronic field data collection in a more efficient and accurate manner compared to the traditional pen and paper.”

The goal
“Our goal is to apply the modern breeding methods we have learnt to release new improved drought- and disease-resistant varieties before the project closes in mid-2014.” Some of these new methods include using quantitative trait loci (QTLs) through marker-assisted selection (MAS) and marker-assisted backcrossing (MABC).

“The results we obtain will provide foundation seed that can then be used for mass production through the Tropical Legumes II project,” says Paul.

“Our task is not complete until we have improved varieties in the hands of farmers,” he concludes.

VIDEO on farmer participation, and the relevance of genomics – Paul and TLI colleagues

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Jun 272012
 
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India is the world’s largest producer and consumer of chickpea, accounting for more than a third (66 percent) of world production.

The Indian Agricultural Research Institute (IARI) and the Indian Institute of Pulses Research (IIPR) are collaborating with the International Crops Research Institute for the Semi-Arid Tropics (ICRISAT) on marker-assisted backcrossing (MABC), to improve chickpeas for drought tolerance.

This complementary activity in the Tropical Legumes I project (TLI) Phase II is being funded by the Department of Biotechnology, Government of India.

Dr N Nadrajan (pictured left), IIPR Director, adds “We have been trained on the breeding tools offered by the Integrated Breeding Platform, including data management, and on electronic data collection using a handheld device.”

Shailesh Tripathi (pictured right) is a Senior Scientist working on chickpea breeding at IARI. “During Phase I of TLI, ICRISAT and its partners identified a root-trait QTL region which confers drought tolerance in chickpeas, and the markers by which to transfer this QTL region. By evaluating the chickpea reference set, ICRISAT and its partners in Africa identified about 40 lines for drought tolerance, and these lines are being used in Phase II of the project,” says Shailesh. [Editor’s note: A ‘reference set’ is a sub-sample of existing germplasm collections that facilitates and enables access to existing crop diversity for desired traits, such as drought tolerance or resistance to disease or pests]

“Through GCP, we have benefitted from training in molecular breeding. The benefits of this go beyond this project,” he adds.

The Indian scientists are using MABC as well as marker-assisted recurrent selection (MARS) in Phase II, applying genomic resources that came from Phase I of the project.

“Our goal is to obtain lines with good root traits for drought tolerance,” says Shailesh, realistically adding that “Variety release will take time, but the good news is that we already have the pre-release materials to identify donors for specific traits, like root biomass.”

Progress in chickpea research in Africa and Asia

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Jun 262012
 
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It’s all about water and weakness  or strength. The Greek legend has it that Achilles was dipped into River Styx by his mother, Thetis, in order to make him invulnerable. His heel wasn’t covered by the water and he later died of the wound from an arrow that struck his heel.

In our times, this analogy can be applied to chickpeas, where this streetwise tough customer in the crop kingdom that thrives on the most rugged terrains is hamstrung if there is no rain at the critical grain-filling period – its sole Achilles’ heel, when it cannot take the searing heat in the drylands it otherwise thrives in.

But before you read on about the latter-day borrowing of this ancient legend, and science’s quest to heal the hit from heat and to cure the crop’s fatal flaw on water, first, an important aside…

Who’s now calling the shots in chickpea research?

Molecular breeding in Phase I was led by ICRISAT, with country partners in a supporting role. In Phase II, activities are being led by country partners, which also assures sustainability and continuity of the work. ICRISAT is now in a facilitating role, providing training and data, while the research work is now in the hands of country partners.” – Pooran Gaur, Principal Scientist: Chickpea Breeding,  ICRISAT.

The facts
Chickpeas are an ancient crop that was first domesticated in central and western Asia. Today, this crop is cultivated in 40 countries and is second only to common beans as the food legume most widely grown by smallholders. The two main types of chickpeas – desi and kabuli – are valuable for both subsistence and cash.

Even for the hardy, times are tough
“Chickpeas are well-known to be drought-tolerant,” says Rajeev K Varshney, Principal Investigator of the project to improve chickpeas work in the Tropical Legumes I Project (TLI). He explains, “The plants are very efficient in using water and possess roots that seek out residual moisture in deeper soil layers.” However, he points out that, with changing climatic conditions, especially in drier areas, terminal drought – when rain does not fall during grain-filling – is the crop’s Achilles’ heel, and principal production constraint.

“Chickpeas are such tough plants that, even for conditions of terminal drought, yields can be increased by improving root characteristics and water-use efficiency,” says Rajeev. The research team has identified several lines with superior traits such as drought tolerance, after screening a set of 300 diverse lines selected based on molecular diversity of large germplasm collections.

VIDEO CLIP: Recipe for chickpea success

Enhancing the genetic makeup to beat the heat
The team went on to develop genomic resources such as molecular markers. With these markers, the team developed a high-density genetic map, and identified a genomic region containing several quantitative trait loci (QTLs), conferring drought tolerance. “QTLs help pinpoint, more specifically, the location of genes that govern particular traits like root length” explains Rajeev.

Longer roots will naturally give the plants a deeper reach into the water table. Root length is the difference between survival and perishing, which is why trees will be left standing on a landscape otherwise laid bare by prolonged drought.

Q for ‘quick’: QTLs speed things along from lab to field, and running with the winners
The discovery of QTLs makes identifying tolerant plants not only easier, but also cheaper and faster. “This means that better-adapted varieties will reach farmers faster, improving food security,” says Rajeev.

Pooran Gaur, GCP’s Product Delivery Coordinator for chickpeas, Principal Scientist for Chickpea Breeding at ICRISAT, and an important collaborator on the TLI project, adds, “We began marker-assisted selection backcrossing (MABC) in Phase I. By 2011, lines were already being evaluated in Ethiopia, India and Kenya. We are now at the stage of singling out the most promising lines.”

Putting chickpeas to the test: Rajeev Varshney (left) and Pooran Gaur (right) inspecting a chickpea field trial.

What was achieved in Phase I, and what outcomes are expected?
Phase I run from mid-2007 to mid-2010, during which time 10 superior lines for improved drought tolerance and insect resistance were identified for Ethiopia, Kenya and India. As well, a total of 1,600 SSR markers and 768 SNPs on GoldenGate assays were developed, along with an expanded DArT array with more than 15,000 features. A high-density reference genetic map and two intraspecific genetic maps were developed.

“We now have materials from marker-assisted backcrossing by using the genomic resources we produced in Phase I. These materials were sent to partners last year [2011]. And because in most cases we have the same people working in TLI as in TLII, this material is being simultaneously evaluated across six to seven locations by all TLI and TLII partners,” says Pooran.

“Preliminary analysis of data is quite encouraging and it seems that we will have drought-tolerant lines soon,” adds Rajeev.

Future work, and who’s now calling the shots in the field
In Phase II, 1,500 SNPs on cost-effective KASPar assays have been developed that have been useful to develop a denser genetic map. In collaboration with University of California–Davis (USA) and the National Institute of Plant Genome Research (India), a physical map has been developed that will help to isolate the genes underlying the QTL region for drought tolerance. A novel molecular breeding approach called marker-assisted recurrent selection (MARS) has been adopted. Over the remaining two years of Phase II, the chickpea work will focus on developing chickpea populations with superior genotypes for drought tolerance through MABC and MARS.

Pooran adds, “Molecular breeding in Phase I was led by ICRISAT, with country partners in a supporting role. In Phase II, activities are being led by country partners, which also assures sustainability and continuity of the work. ICRISAT is now in a facilitating role, providing training and data, while the MABC and MARS aspects are both in the hands of country partners.”

“Another important activity in Phase II is development of multi-parents advanced generation intercross (MAGIC) population that will help generation of genetic populations with enhanced genetic diversity,” says Rajeev.

Partnerships
The chickpea work is led by the International Crops Research Institute for the Semi-Arid Tropics (ICRISAT), working with partners at the Ethiopian Institute of Agricultural Research, Egerton University in Kenya, and the Indian Agricultural Research Institute. Additional collaborators in Phase I included the University of California–Davis (USA), the National Center for Genome Resources (USA) and DArT P/L (Australia).

For more information on the overall work in chickpeas, please contact Rajeev K Varshney, Principal Investigator of the chickpea work.

Video: Featuring Rajeev and partners Fikre Asnake (Ethiopia) and Paul Kimurto (Kenya)

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