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Aug 292014
 

“…I wanted to contribute in a similar way” – Eva Weltzien

 

Eva Weltzien

Eva Weltzien

Learning about the work of Nobel laureate, Norman Borlaug, in high school inspired Eva Weltzien to become a plant breeder so she too could contribute to improving the living conditions in the developing world. Today, Eva is a Principal Scientist in sorghum breeding and genetic resources at the International Crops Research Institute for the Semi-Arid Tropics (ICRISAT) in Mali.

“Not only did Norman Borlaug revolutionise agriculture by breeding high-yielding wheat varieties, he then selflessly distributed these to the countries in the world that most needed them, saving hundreds of millions from starvation,” Eva recollects passionately, as she speaks about her scientific hero. “I remember being inspired when he won his Nobel Prize in 1970, mainly for the fact that agricultural research was actually being seen as contributing to world peace,” says Eva. “I knew then that I wanted to contribute in a similar way.”

I…wanted to take a break from… theory and instead gain an appreciation for plant breeding by working in the field”

The path to plant breeding, and pearls along the way
Eva was raised in her native Germany, as well as in Beirut, Lebanon, where she spent six years when her parents were stationed at the local university there. She credits her parents; both plant pathologists, for instilling in her a scientific mind-set from a tender age.

“They taught me to think outside the box and apply my knowledge and understanding to how I made sense of the world,” Eva recalls. “Being plant pathologists, they also encouraged me to observe the environment carefully and treat the earth with respect.”

Upon graduating from high school, Eva deferred going to university and instead worked as a seed technician for a private company in Germany. “I just wanted to take a break from studying theory and instead gain an appreciation for plant breeding by working in the field,” says Eva.

After one year with the company, Eva was ready to start university. During the decade that followed, she completed a Diploma in Agricultural Biology (University of Hohenheim, 1981) and a PhD in Agriculture (Munich University, 1986).

A year after completing her PhD, Eva accepted a postdoc position at Iowa State University, USA, where she met her future husband Fred Rattunde. After a few years, both Eva and Fred moved to India to work with ICRISAT. “I’ve been working for ICRISAT for almost 27 years now,” says Eva. “When I first started, I was working in pearl millet breeding.”

The key challenges have been improving the infrastructure of the national research facilities… as well as increasing the technical training for local researchers…this has slowly improved, particularly in the last four years with the funding and help through the GCP Sorghum Research Initiative.…we can see our work making an impact on people’s lives…”

Off to Africa, and bearing fruit
In 1998, ICRISAT offered Eva and Fred positions in Mali where they would take responsibility for the Institute’s sorghum-breeding programme in West Africa.

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Evaluating Eva: In Dioila district, Mali, evaluating the panicles of a new sorghum line after harvest.

“It was a great challenge that we both wanted to explore,” says Eva. “The key challenges have been improving the infrastructure of the national research facilities to do the research as well as increasing the technical training for local agronomists and researchers. Over the past 15 years, this has slowly improved, particularly in the last four years, with the funding and facilitation through the GCP Sorghum Research Initiative. Now we can see our work making an impact on people’s lives in West Africa.” (see GCP’s work on infrastructure improvement)

…we are closer to delivering more robust sorghum varieties which will help farmers and feed the ever-growing population in West Africa.”

Improving drought tolerance in sorghum for Africa
The second phase of GCP’s Sorghum Research Initiative focuses on Mali, where sorghum-growing areas are large, and distributed over a wide range of rainfall regimes.

Eva and her team are currently collaborating with local researchers at L’Institut d’économie rurale (IER), Mali and France’s Centre de coopération internationale en recherche agronomique pour le développement (CIRAD) on a project to test a novel molecular-breeding approach – backcross nested association mapping (BCNAM). Eva says the approach has the potential to halve the time it takes to develop local sorghum varieties with improved yield and adaptability to poor soil fertility conditions.

“We don’t have these type of molecular-breeding resources available in Mali, so it’s really exciting to be a part of this project.”  Still, Eva and her colleagues continue to press forwards in this new frontier in plant science, making good advances in another parallel but closely related project that Eva leads in the GCP Comparative Genomics Research Initiative.

Eva continues, “We’ve had good results in terms of field trials, despite the political situation. Overall, we feel the experience is enhancing our capacity here in Mali, and that we are closer to delivering more robust sorghum varieties which will help farmers and feed the ever-growing population in West Africa.”

Slides (with more links after the slides)

Links

Aug 272014
 
Leon Kochian

Leon Kochian

“By being involved with GCP, I’ve had more opportunities to travel to the developing world and witness the problems that local farmers in these countries are facing, as well as to meet with the local researchers who are trying to overcome these problems. It has made me appreciate that these  researchers also need the capacity to sustainably deal with agricultural problems once the project money starts to dry up.” – Leon Kochian (pictured), Professor, Cornell University, USA; and Director of Robert W Holley Center for Agriculture and Health, United States Department of Agriculture – Agricultural Research Service. Also Product Delivery Leader for GCP’s Comparative Genomics Research Initiative.

Bright and early beginnings in biology
For as long as Leon Kochian can remember, he’d always wanted to be a biologist.

“I remember my second-grade teacher reading a story to us about the white cliffs of Dover and thinking to myself ‘They’re white because they’re covered in the prehistoric remains of dead protozoan’,”’ says Leon with a chuckle. “Yes, I was a weird kid and that sort of stuff [biology] has always interested me.”

Having completed a Bachelor’s Degree in Botany at the University of California, Berkeley, and a PhD in Plant Physiology at the University of California, Davis (both in USA), Leon joined the United States Department of Agriculture based at Cornell University.

For 30 years, he has combined lecturing and supervising duties at Cornell, with his quest to understand the genetic and physiological mechanisms that allow some cereals to tolerate acidic soils.

The GCP model has always attracted me, particularly its focus on making an impact on farmers’ lives… I had already been a successful researcher having published more than 250 papers, but I felt little of that had made any real impact on the world.”

Identifying genes and breeding tolerant crops for African farmers
Leon and Cornell University have been involved with GCP since the Programme’s inception in 2004, playing a lead role in GCP’s Comparative Genomics Research Initiative, of which Leon is the Product Delivery Coordinator. Cornell University is a member of the GCP Consortium, with Leon as Cornell’s representative in the GCP Consortium Committee.

“The GCP model has always attracted me, particularly its focus on making an impact on farmers’ lives,” says Leon, who has been a Principal Investigator for several Comparative Genomics Research Initiative projects. “I had already been a successful researcher having published more than 250 papers, but I felt little of that had made any real impact on the world.”

During the first phase of the project, Leon led a team comprising of researchers from Cornell, EMBRAPA in Brazil and Moi University in Kenya.

In the foreground, left to right, Leon, Jura and Sam in a maize field in Kenya.

Leon (left) with project colleagues, Jurandir Magalhães (EMBRAPA) and Sam Gudu (Moi University) in a maize field in Kenya in May 2010.

“We had been working for many years with both EMBRAPA and Moi University to identify the genes associated with aluminium tolerance in sorghum and maize and saw the potential to apply our research and expand it to explore other cereals such as rice and wheat,” explains Leon.

During GCP Phase I (2004–2008), the team successfully identified and cloned the major sorghum aluminium tolerance gene (AltSB). In Phase II (2009–2014), they are working towards breeding aluminium-tolerant sorghum lines for sub-Saharan Africa as well as applying what they have learnt to discover similar genes in rice and maize.

“Aluminium toxicity is a problem all over the world, but more so in Africa, as most farmers don’t have the money to manage it,” says Leon “These new aluminium-tolerant crops will improve African farmers’ yields, and, in turn, improve their quality of life.”

It’s like match.com for collaborative research and will hopefully foster greater collaboration between the two continents.”

Insights, connections and matchmaking
According to Leon, the funding from GCP has been very beneficial in making significant research progress on the projects he’s been involved with so far, and he is also quick to note the unexpected and very welcome non-monetary benefits from being involved with GCP.

“By being involved with GCP, I’ve had more opportunities to travel to the developing world and witness the problems that local farmers in these countries are facing, as well as to meet with the local researchers who are trying to overcome these problems. It has made me appreciate that these  researchers also need the capacity to sustainably deal with agricultural problems once the project money starts to dry up.”

Working with GCP, Leon has designed and run workshops to train African scientists on molecular breeding techniques and hosted several postgraduate researchers at Cornell. He is now working with GCP collaborators to develop a database that will help African scientists find potential collaborators in USA and the rest of the Americas. “It’s like match.com for collaborative research and will hopefully foster greater collaboration between the two continents,” says Leon.

Research is such a fun and social experience! … I still love getting into the lab and discovering new things. I’ve also learnt to enjoy being the old guy in the lab!”

Growing greyer, growing wiser
Leon says his passion for biology and research is steadfast and has not waned through the years. Although he doesn’t get to do much of the hands-on work these days, it still remains the most enjoyable part of his job. “Research is such a fun and social experience! I still love getting into the lab and discovering new things. I’ve also learnt to enjoy being the old guy in the lab! Just watching and helping young researchers grow and develop their skills is really rewarding. Each of the 13 PhD students I’ve supervised is like one of my kids and I still keep in touch with all of them, as I do with my own PhD supervisor, 30 years on!”

Having recently celebrated his 60th birthday, Leon has no plans on slowing down anytime soon. “I’m currently Director of the Robert W Holley Center for Agriculture and Health, lecturing undergraduate and postgraduate students, supervising two PhD students and sitting on several boards, all the while trying to find time to write papers and do some research. It’s hard work but I enjoy it.”

The three faces of Leon: (1) in the lab in Cornell; (2) in the field courtesy of USDA-ARS; and, (3) delivering opening remarks as Director of the Robert W Holley Center

The three faces of Leon: (1) in the lab in Cornell; (2) in the field, courtesy of USDA–ARS; and, (3) delivering opening remarks as Director of the Robert W Holley Center.

Leon tries to impart this philosophy to his students, believing scientists need to enjoy what they are doing, work hard at it, be flexible and creative, and, most importantly, not have ‘fear of failure’. “I don’t care how smart you are. If you’re not willing to work really hard and learn to improve yourself, then you’re not going to succeed.”

With regard to his GCP projects soon coming to a close when GCP sunsets in December 2014, Leon hopes he and team will succeed in meeting all their goals, but even if they don’t, he’s sure they’ll continue the research and try to discover more about aluminium tolerance. More power to them!

Leon’s slides, with links to more supplementary material after the slides

Links

Aug 152014
 

 

Samuel Gudu

Samuel Gudu

Having funding to support PhD students and provide them with the resources they need to complete their research is very fulfilling and will go a long way to enhance the long-term success of our goal: to provide Kenyan farmers with cereal varieties that will improve their yields and make their livelihood more secure and sustainable.” – Samuel Gudu, Professor and Deputy Vice-Chancellor (Planning & Development) at Moi University, and now Principal, Rongo University College: a Constituent College of Moi University, Kenya.

Growing up, and getting dirty
Learner, teacher and leader. Sam Gudu has been all these, but this doesn’t mean he doesn’t like to get his hands dirty.

Growing up in a small fishing village on the banks of Lake Victoria, in Western Kenya, Sam was always helping his parents to fish and garden, or his grandparents to muster cattle.

“I remember spending long hours before and after school either on the lake or in the field helping to catch, harvest and produce enough food to eat and support our family,” reminisces Sam.

He attributes this “hard and honest” work to why he still enjoys being in the field.

“Even though I now spend most of my days doing administration work, I’m always trying to get out into the field to get my hands dirty and see how our research is helping to make the lives of Kenyan farmers a lot more profitable and sustainable,” he says.

Sam in a maize field in Kenya.

Doing what he likes to do best: Sam in a maize field in Kenya.

I was… captivated by the study of genetics as it focused on what controlled life.”

Taking control: bonded to genetics, at home and away
Sam says his love for the land transferred to an interest and then passion in the classroom during high school. “I became very interested in Biology as I wanted to know how nature worked,” says Sam. “I was particularly captivated by the study of genetics as it focused on what controlled life.”

This interest grew during his undergraduate years at the University of Nairobi where he completed a Bachelor of Science in Agriculture and a Master’s of Science in Agriculture, focusing on genetics and plant breeding.

“I fondly remember a lecturer during my master’s degree studies who would continually give us challenges to test in the field and in the lab. If you had a viable idea he supported you to design an experiment to test your theory. I like to use the same method in teaching my students. I discuss quite a lot with my students and I encourage them to disagree if they use scientific process.”

Driven by an ever-growing passion and enthusiasm, Sam secured a scholarship to travel to Canada to undertake a PhD in Plant Genetics and Biotechnology at the University of Guelph.

[There has been an] influx of young Kenyans who are choosing degrees in science. The Kenyan Government has recently increased its funding for science and research…”

Nurturing the next breed of geneticists
After graduating from Guelph in 1993, Sam returned to Kenya to lecture at Moi University where he initiated and helped expand teaching and research in the disciplines of Genetic Engineering, Biotechnology and Molecular Biology.

In the past two decades, he has recruited young talented graduates in genetics and helped acquire advanced laboratory equipment that has enabled practical teaching and research in molecular biology.

“I wouldn’t be where I am now were it not for all the assistance I received from my teachers, lecturers and supervisors; notably my PhD supervisor – Prof Ken Kasha of the University of Guelph. So I’ve always tried my best to give the same assistance to my students. It’s been hard work but very rewarding, especially when you see your students graduate to become peers and colleagues.” (Meet some of Sam’s students)

Sam (2nd right), with some of his young charges: Thomas Matonyei (far left) , Edward Saina (2nd left) and Evans Ouma (far right)

Sam (2nd right), with some of his young charges: Thomas Matonyei (far left), Edward Saina (2nd left) and Evans Ouma (far right).

Sam is particularly buoyed by the influx of young Kenyans who are choosing degrees in science.

“The Kenyan Government has recently increased its funding for science and research to two percent of GDP,” explains Sam. “This has not only helped us compete in the world of research but has helped raise the profile of science as a career.”

Knowing which genes are responsible for aluminium tolerance will allow us to more precisely select for aluminium tolerance in our breeding programmes, reducing the time it takes for us to breed varieties that will have improved yields in acidic soils without the use of costly inputs such as lime or fertiliser.” (See the work that Sam does in this area with other partners outside Kenya)

So far we have produced 10 inbred lines that are outstanding for phosphorus efficiency, and two that were outstanding for aluminium toxicity. We are now testing unique verities developed for acid soils of Kenya.”

Slashing costs, increasing yields and resilience: genes to the rescue
Currently, Sam and his team of young researchers at Moi University are working with several other research facilities around the world (Brazilian Agricultural Research Corporation, EMBRAPA; Cornell University, USA; the International Rice Research Institute (IRRI); Japan’s International Research Center for Agricultural Sciences, JIRCAS; and the Kenya Agricultural Research Institute, KARI–Kitale) to develop high-yielding maize varieties adapted to acid soils in East Africa, using molecular and conventional breeding approaches.

Can you spot Sam? It’s a dual life. Here, he sheds his field clothes in this 2011 suit-and-tie moment with Moi University and other colleagues involved in the projects he leads. Left to right: P Kisinyo, J Agalo, V Mugalavai, B Were, D Ligeyo, S Gudu, R Okalebo and A Onkware.

Acid soils cover almost 13 per cent of arable land in Kenya, and most of the maize-growing areas in Kenya. In most of these areas, maize yields are reduced by almost 60 per cent. Aluminium toxicity is partly responsible for the low and declining yields.

“We found that most local maize varieties and landraces grown in acid soils are sensitive to aluminium toxicity. The aluminium reduces root growth and as such the plant cannot efficiently tap into native soil phosphorus, or even added phosphorus fertiliser. However, there are some varieties of maize that are suited to the conditions even if you don’t use lime to improve the soil’s pH. So far we have produced 10 inbred lines that are outstanding for phosphorus efficiency, and two that were outstanding for aluminium toxicity. We are now testing unique varieties developed for acid soils of Kenya.”

Sam (left)   a group of farmers and alking to farmers and researchers at Sega, Western Kenya, in June 2009

Sam (left) addressing a mixed group of farmers and researchers at Sega, Western Kenya, in June 2009.

In a related project, Sam is working with the same partners to understand the molecular and genetic basis for aluminium tolerance.

“Knowing which genes are responsible for aluminium tolerance will allow us to more precisely select for aluminium tolerance in our breeding programmes, reducing the time it takes for us to breed varieties that will have improved yields in acidic soils without the use of costly inputs such as lime or fertiliser.”

 … my greatest achievements thus far have been those which have benefited farmers and my students.”

 Summing up success
For Sam, the greatest two successes in his career have not been personal.

“If I’m honest, I have to say my greatest achievements thus far have been those which have benefited farmers and my students. Having funding to support PhD students and provide them with the resources they need to complete their research is very fulfilling and will go a long way to enhance the long-term success of our goal: to provide Kenyan farmers with cereal varieties that will improve their yields and make their livelihoods more secure and sustainable.”

With a dozen aluminium-tolerant and phosphorus-efficient breeding lines under their belt already, and two lines submitted for National Variety Trials (a pre-requisite step to registration and release to farmers), Sam and his team seem well on their way towards their goal, and we wish them well in their quest and labour.

Links:

 

Jul 232014
 

 

DNA spiral

DNA spiral

Crop researchers including plant breeders across five continents are collaborating on several GCP projects to develop local varieties of sorghum, maize and rice, which can withstand phosphorus deficiency and aluminium toxicity – two of the most widespread constraints leading to poor crop productivity in acidic soils. These soils account for nearly half the world’s arable soils, with the problem particularly pronounced in the tropics, where few smallholder farmers can afford the costly farm inputs to mitigate the problems. Fortunately, science has a solution, working with nature and the plants’ own defences, and capitalising on cereal ‘family history’ from 65 million years ago. Read on in this riveting story related by scientists, that will carry you from USA to Africa and Asia with a critical stopover in Brazil and back again, so ….

… welcome to Brazil, where there is more going than the 2014 football World Cup! Turning from sports to matters cerebral and science, drive six hours northwest from Rio de Janeiro and you’ll arrive in Sete Lagoas, nerve centre of the EMBRAPA Maize and Sorghum Research Centre. EMBRAPA stands for Empresa Brasileira de Pesquisa Agropecuária  ‒  in  English, the Brazilian Agricultural Research Corporation.

Jura_w

Jurandir Magalhães

Jurandir Magalhães (pictured), or Jura as he prefers to be called, is a cereal molecular geneticist and principal scientist who’s been at EMBRAPA since 2002.

“EMBRAPA develops projects and research to produce, adapt and diffuse knowledge and technologies in maize and sorghum production by the efficient and rational use of natural resources,” Jura explains.

Such business is also GCP’s bread and butter. So when in 2004, Jura and his former PhD supervisor at Cornell University, Leon Kochian, submitted their first GCP project proposal to clone a major aluminium tolerance gene in sorghum they had been searching for, GCP approved the proposal.

“We were already in the process of cloning the AltSB gene,” remembers Jura, “So when this opportunity came along from GCP, we thought it would provide us with the appropriate conditions to carry this out and complete the work.”

Cloning the AltSB gene would prove to be one of the first steps in GCP’s foundation sorghum and maize projects, both of which seek to provide farmers in the developing world with crops that will not only survive but thrive in the acidic soils that make up more than half of the world’s arable soils (see map below).

More than half of world’s potentially arable soils are highly acidic.

More than half of world’s potentially arable soils are highly acidic.

… identifying the AltSB gene was a significant achievement which brought the project closer to their final objective, which is to breed aluminium-tolerant crops that will improve yields in harsh environments, in turn improving the quality of life for farmers.”

A star is born: identifying and cloning AltSB
For 30 years, Leon Kochian (pictured below) has combined lecturing and supervising duties at Cornell University and the United States Department of Agriculture, with his quest to understand the genetic and physiological mechanisms behind the ability of some cereals to withstand acidic soils. Leon is also the Product Delivery Coordinator for GCP’s Comparative Genomics Research Initiative.

Leon Kochian

Leon Kochian

Aluminium toxicity is associated with acidic soils and is the primary limitation on crop production for more than 30 percent of farmland in Southeast Asia and Latin America, and approximately 20 percent in East Asia, sub-Saharan Africa and North America. Aluminium ions damage roots and impair their growth and function. This results in reduced nutrient and water uptake, which in turn depresses yield.

“These effects can be limited by applying lime to increase the soil’s pH. However, this isn’t a viable option for farmers in developing countries,” says Leon, who was the Principal Investigator for the premier AltSB project and is currently involved in several off-shoot projects.

Working on the understanding that grasses like barley and wheat use membrane transporters to insulate themselves against subsoil aluminium, Leon and Jura searched for a similar transporter in sorghum varieties that were known to tolerate aluminium.

“In wheat, when aluminium levels are high, these membrane transporters prompt organic acid release from the tip of the root,” explains Leon. “The organic acid binds with the aluminium ion, preventing it from entering the root. We found that in certain sorghum varieties, AltSB is the gene that encodes a specialised organic acid transport protein – SbMATE*  –  which mediates the release of citric acid. From cloning the gene, we found it is highly expressed in aluminium-tolerant sorghum varieties. We also found that the expression increases the longer the plant is exposed to high levels of aluminium.”

[*Editor’s note: different from the gene with the same name, hence not in italics]

Leon says identifying the AltSB gene and then cloning it was a significant achievement and it brought the project closer to their final objective, which he says is “to breed aluminium-tolerant crops that will improve yields in harsh environments, in turn improving the quality of life for farmers.”

This research was long and intensive, but it set a firm foundation for the work in GCP Phase II, which seeks to use what we have learnt in the laboratory and apply it to breed crops that are tolerant to biotic or abiotic stress such as aluminium toxicity and phosphorus deficiency.”

Comparative genomics: finding similar genes in different crops
Wheat, maize, sorghum and rice are all part of the Poaceae (grasses) family, evolving from a common grass ancestor 65 million years ago. Over this time they have become very different from each other. However, at a genetic level they still have a lot in common.

Over the last 20 years, genetic researchers all over the world have been mapping these cereals’ genomes. These maps are now being used by geneticists and plant breeders to identify similarities and differences between the genes of different cereal species. This process is termed comparative genomics and is a fundamental research theme for GCP research as part of its second phase.

rajeev-varshney_1332450938

Rajeev Varshney

“The objective during GCP Phase I was to study the genomes of important crops and identify genes conferring resistance or tolerance to biotic or abiotic stresses,” says Rajeev Varshney (pictured), Director, Center of Excellence in Genomics and Principal Scientist in applied genomics at the International Crops Research Institute for the Semi-Arid Tropics (ICRISAT). “This research was long and intensive, but it set a firm foundation for the work in GCP Phase II, which seeks to use what we have learnt in the laboratory and apply it to breed crops that are tolerant to biotic or abiotic stress such as aluminium toxicity and phosphorus deficiency.”

Until August 2013, Rajeev had oversight on GCP’s comparative genomics research projects on aluminium tolerance and phosphorus deficiency is sorghum, maize and rice, as part of his GCP role as Leader of the Comparative and Applied Genomics Theme.

“Phosphorus deficiency and aluminium toxicity are soil problems that typically coincide in acidic soils,” says Rajeev. “They are two of the most critical constraints responsible for low crop productivity on acid soils worldwide. These projects are combining the aluminium tolerance work done by EMBRAPA and Cornell University with the phosphorus efficiency work done by IRRI [International Rice Research Institute] and JIRCAS [Japan International Research Centre for Agricultural Sciences] to first identify and validate similar aluminium-tolerance and phosphorus-efficient genes in sorghum, maize and rice, and then, secondly, breed crops with these combined improvements.”

These collaborations are really exciting! They make it possible to answer questions that we could not answer ourselves, or that we would have overlooked, were it not for the partnerships.”

When AltSB met Pup1
Having spent more than a decade identifying and cloning AltSB, Jura and Leon have recently turned their attention to identifying and cloning the genes responsible for phosphorus efficiency in sorghum. Luckily, they weren’t starting from scratch this time, as another GCP project on the other side of the world was well on the way to identifying a phosphorus-efficiency gene in rice.

Led by Matthias Wissuwa at JIRCAS and Sigrid Heuer at IRRI, the Asian base GCP project had identified a gene locus, which encoded a particular protein kinase that allowed varieties with this gene to grow successfully in low-phosphorous conditions. They termed the region of the rice genome where this gene resides as ‘phosphorus uptake 1’ or Pup1 as it is commonly referred to in short.

“In phosphorus-poor soils, this protein kinase instructs the plant to grow larger, longer roots, which are able to forage through more soil to absorb and store more nutrients,” explains Sigrid. “By having a larger root surface area, plants can explore a greater area in the soil and find more phosphorus than usual. It’s like having a larger sponge to absorb more water!”

Read more about the mechanics of Pup-1 and the evolution of the project.

Jura and Leon are working on the same theory as IRRI and JIRCAS, that larger and longer roots enhance phosphorus efficiency. They are identifying sorghum with these traits, using comparative genomics to identify a locus similar to Pup1 in these low-phosphorus-tolerant varieties, and then verify whether the genes at this locus are responsible for the trait.

“So far, the results are promising and we have evidence that Pup1 homologues may underlie a major QTL for phosphorous uptake in sorghum,” says Jura who is leading the project to identify and validate Pup1 and other phosphorus-efficiency QTLs in sorghum.  QTL stands for ‘quantitative trait locus’ which refers to stretches of DNA containing ‒ or linked to ‒ the genes responsible for a quantitative trait  “What we have to do now is to see if this carries over in the field, leading to enhanced phosphorus uptake and grain yield in low-phosphorus soils,” he adds.

Jura and Leon are also returning the favour to IRRI and JIRCAS and are collaborating with both institutes to identify and clone in rice similar genes to the AltSB gene in sorghum.

“These collaborations are really exciting! They make it possible to answer questions that we could not answer ourselves, or that we would have overlooked, were it not for the partnerships,” says Sigrid.

To make a difference in rural development, to truly contribute to improved food security through crop improvement and incomes for poor farmers, we knew that capacity development had to be a continuing cornerstone in our strategy.”

Building capacity in Africa
In GCP Phase II which is more application oriented, projects must have objectives that deliver products and build capacity in developing-world breeding programmes.

Jean-Marcel Ribaut

Jean-Marcel Ribaut

“The thought behind the latter requirement is that GCP is not going to be around after 2014 so we need to facilitate these country breeding programmes to take ownership of the science and products so they can continue it locally,” says Jean-Marcel Ribaut, GCP Director (pictured). “To make a difference in rural development, to truly contribute to improved food security through crop improvement and incomes for poor farmers, we knew that capacity development had to be a continuing cornerstone in our strategy.”

Back to Brazil: Jura says this requirement is not uncommon for EMBRAPA projects as the Brazilian government seeks to become a world leader in science and agriculture. “Before GCP started, we had been working with African partners for five to six years through the McKnight Project. It was great when GCP came along as we were able to continue these collaborations.”

Samuel Gudu

Samuel Gudu

One collaboration Jura was most pleased to continue was with his colleague and friend, Sam Gudu (pictured), from Moi University, Kenya. Sam has been collaborating with Jura and Leon on several GCP projects and is the only African Principal Investigator in the Comparative Genomics Research Initiative.

“Our relationship with EMBRAPA and Cornell University has been very fruitful,” says Sam. “We wouldn’t have been able to do as much as we have done without these collaborations or without our other international collaborators at IRRI, JIRCAS, ICRISAT or Niger’s National Institute of Agricultural Research [INRAN].”

Sam is currently working on several projects with these partners looking at validating the genes underlying major aluminium-tolerance and phosphorus-efficiency traits in local sorghum and maize varieties in Kenya, as well as establishing a molecular breeding programme.

“The molecular-marker work has been very interesting. We have selected the best phosphorus-efficient lines from Brazil and Kenya, and have crossed them with local varieties to produce several really good hybrids which we are currently field-testing in Kenya,” explains Sam. “Learning and using these new breeding techniques will enable us to select for and breed new varieties faster.”

Sam is also grateful to both EMBRAPA and Cornell University for hosting several PhD students as part of the project. “This has been a significant outcome as these PhD students are returning to Kenya with a far greater understanding of molecular breeding which they are sharing with us to advance our national breeding programme.”

We’ve used the knowledge that Jura’s and Leon’s AltSB projects have produced to discover and validate similar genes in maize…We identified Kenyan lines carrying the superior allele of ZmMATE …This work will also improve our understanding of what other mechanisms may be working in the Brazilian lines too.” 

‘Everyone’ benefits! Applying the AltSB gene to maize
Claudia Guimarães (pictured) is a maize geneticist at EMBRAPA. But unlike Jura, her interest lies in maize.

Claudia

Claudia Guimarães

Working on the same comparative genomics principle used to identify Pup1 in sorghum, Claudia has been leading a GCP project replicating the sorghum aluminium tolerance work in maize.

“We’ve used the knowledge that Jura’s and Leon’s AltSBprojects have produced to discover and validate similar genes in maize,” explains Claudia. “From our mapping work we identified ZmMATE as the gene underlying a major aluminium tolerance QTL in maize. It has a similar sequence as the gene found in sorghum and it encodes a similar protein membrane transporter that is responsible for citrate extradition.”

A maize field at EMBRAPA. Maize on the left is aluminum-tolerant while the maize on the right is not.

A maize field at EMBRAPA. Maize on the left is aluminium-tolerant while the maize on the right is not.

Using molecular markers, Claudia and her team of researchers from EMBRAPA, Cornell University and Moi University have developed near-isogenic lines from Brazilian and Kenyan maize varieties that show aluminium tolerance, with ZmMATE present. From preliminary field tests, the Brazilian lines have had improved yields in acidic soils.

“We identified a few Kenyan lines carrying the superior allele of ZmMATE that can be used as donors to develop maize varieties with improved aluminium tolerance,” says Claudia.  “This work will also improve our understanding of what other mechanisms may be working in the Brazilian lines too.”

What has pleased Jura and other Principal Investigators the most is the leadership that African partners have taken in GCP projects.

Cherry on the cereal cake
With GCP coming to an end in December 2014, Jura is hopeful that his and other offshoot projects dealing with aluminium tolerance and phosphorus efficiency will deliver on what they set out to do.

“For me, the cherry on the cake for the aluminium-tolerance projects would be if we show that AltSB improves tolerance in acidic soils in Africa. If everything goes well, I think this will be possible as we have already developed molecular markers for AltSB.”

What has pleased Jura and other Principal Investigators the most is the leadership that African partners have taken in GCP projects.

“This has been a credit to them and all those involved to help build their capacity and encourage them to take the lead. I feel this will help sustain the projects into the future and one day help these developing countries produce varieties of sorghum and maize for their farmers that are able to yield just as well in acidic soils as they do in non-acidic soils.”

In the foreground, left to right, Leon, Jura and Sam in a maize field in Kenya.

In the foreground, left to right, Leon, Jura and Sam in a maize field at the Kenya Agricultural Research Institute (KARI), Kitale, in May 2010. They are examining crosses between Kenyan and Brazilian maize germplasm.

Links

 

 

Nov 122013
 

 

 

Participants at the 2013 GRM. High-resolution version on Flickr: http://bit.ly/1fxhkmQ

Participants at the 2013 GRM. High-resolution version on our Flickr account.

The General Research Meeting (GRM) is by far the largest and most important event on our calendar. This year’s GRM was held on September 27‒30 2013, with 135 people from 35 countries attending (see list).

Various presentations were made on progress and next steps on research in GCP projects, including for GCP’s Integrated Breeding Platform (IBP). Focus was on GCP’s nine focus crops in Phase II – beans, cassava, chickpeas, cowpeas, groundnuts, maize, rice, sorghum and wheat, with the poster sessions adding a couple more (see ‘sixty posters’ below). You can view the presentations made on our website  (to see them in the context of the overall agenda), or on SlideShare (all gathered in one place).  We have uploaded all but one presentation, where we’re still waiting for the presenter’s permission to publish. A comprehensive update on all GCP projects is here (PDF). The meeting was a blend of plenary sessions on core topics and research updates, and ‘drill-down’ breakouts on crops, data management and capacity building (the last two, in the context of IBP’s proposed Phase II, which had its own dedicated one-day stakeholder meeting after GRM, on 1st October).DSC07162_w

Social were we…but we also did some heavy lifting
We didn’t just talk to ourselves: we made a bit of noise on social media to also bring in other voices into the GRM discourse and chit-chat, using the hashtag #GRM13, creating a good buzz of conversations. Also linking in to GRM were our LinkedIn followers. And neither was it all business, science and rigid structure: there was free-flow too, with an open afternoon where participants could take a relaxing break, organise their own meetings, or take a tour to Lisbon. Some of the scenes from the tour are posted on Flickr, as are other snapshots from the meeting. We’ve since gathered up some of the social media posts on Storify.

GRM was far from its grim-sounding  abbreviation and hashtag on social media:  exemplifying the best of the ‘GCP spirit’,  the sessions were engaging, relaxed, conversational and spiced with humour and a light touch, despite the ‘heavy’ topics under discussion (see agenda). But the topic at hand was grim, since the situation is dire – drought affects almost all crops and all regions worldwide. As drought tolerance is our key focus since inception, most of the discussions naturally centred on this topic. Equally important is the scourge wrought by pests and disease, which afflict some crops more than others. For example, under most circumstance, cassava is naturally very drought-tolerant, but what good will this do if cassava survives drought only to succumb to the deadly pests and diseases that stalk this drought champion?

Sunset and ‘moon-rise’
GRM was also a time for both stocktaking and mapping the future  given GCP’s sunset in 2014.  A central and recurring theme was GCP’s transition strategy, and how – and where – to embed GCP-initiated projects that will extend beyond the Programme’s lifetime. For this, the CGIAR Research Programs (CRPs) are a natural first choice. GRM enjoyed a very good representation of the CRPs, with all six crop CRPs represented, some at the highest level.

A few members of our Executive Board also attended. Board Chair, Andrew Bennett, set the right tone for the meeting. In his remarks at the opening session, he emphasised that this was not a time for sadness, swan songs and moping as GCP approaches sunset.  Rather, it was a time to appreciate the beauty of sunsets, in the sure knowledge that sunsets give rise to  moon-rise!

A section of Poster Session II presenters. IN the foreground, Andrew Bennett, Chair, GCP Excecutive Board.

A section of Poster Session II presenters. In the foreground, Andrew Bennett, Chair, GCP Executive Board.

“Say it succinctly in sixty seconds!”
The poster session was as lively as always, with a record of… (hold your breath!) 60 posters presented, surpassing the previous GRM in 2011 which attracted 53 posters.

Perfection!  Sixty posters for sixty seconds
Sixty was a PERFECT number for the 60-second sizzle, where each poster presenter had a maximum of 60 seconds (and not a second more!) to present at plenary, devising whichever means necessary to attract the audience to their poster. It was easy to discern the brash ‘old hands’ who had perfected their art after several GRMs; the tricksters and various reincarnations of The Artful Dodger amongst them, trying to beat the clock; new and slightly jittery presenters who were more than just a little bewildered but still proved their mettle; and the new, sassy and confident. This beautiful blend apart, the poster session brought in not only new faces to add to the familiar ones, but also refreshing new tastes to diversify and sweeten our Staple of Nine crops. To our diet of cereals, legumes and tubers, poster presenters from The Philippines added eggplants, rounded off with bananas for dessert.

"Definitely time for dessert, and do not disturb!" they seem to be saying. Jean-Christophe Glaszmann (left) and Hei Leung (right), who played ace roles on a multi-partner GCP project on bananas.

“Definitely time for dessert, and do not disturb!” they seem to be saying. Jean-Christophe Glaszmann (left) and Hei Leung (right), who played ace roles on a multi-partner GCP project on bananas.

♫ Welcome to the Hotel California! ♫…
As always, GRM was a mingling of old and new friends, a time for some paths to meet and for new forks to branch out, a season to reflectively look back and progressively face forwards. In keeping with Andrew’s continuity of sunsets giving way to moonrise, we said a group goodbye to Rajeev Varshney, former Genomics Theme Leader, who left the GCP Management Team in August. And we were happy to once again welcome, embrace and recognise two old friends – Jean Christophe Glaszmann (CIRAD) and Hei Leung (IRRI), who were, respectively ex-Subprogramme Leaders for genetic diversity and genomics in GCP Phase I, and continue to be involved with GCP as researchers, as will Rajeev.

In this picture, we caught up with them at a very appropriate moment: dessert during the Gala Dinner. Take it from us, these two guys are well versed in matters dessert, with a dash of science, as this blast from the past on bananas attests, also summarised in a Facebook photo-story here.

We are indeed a Hotel California of sorts – always open for check-in and checkout. As for leaving…we’re still working on the modalities of that!

And despite the fond farewell, truth is Rajeev is not going anywhere either, as far as GCP is concerned. You only needed to have been at GRM or following the conversations on Facebook and Twitter, especially the photos, to witness this. He was (delightfully!) all over the place, passing on his ‘positive epidemic’ of highly infectious enthusiasm and incredible energy. Here he is in action at the Gala Dinner in the photos below, which really need no caption. We’re sure you’ll be able to easily spot Rajeev, ‘high-fivin’ and ‘rapping’, eclipsing the GCP Director, who however appears quite pleased in his lower perch with Rajeev on the platform. But if you’re truly lost and can’t spot the super-charged high-energy guy in the photos, no worries! Here are some handy clues.

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In distinguished company
Rajeev’s energy goes beyond GRM and GCP; this year as in previous ones, he received several awards, among them, the Young Crop Scientist Award by Crop Science Society of America, and the Illumina Agriculture Greater Good Initiative Award.

Hari Upadhyaya

Hari Upadhyaya

Prior to these recognitions during the Gala Dinner, Jean-Marcel formally honoured ICRISAT’s Hari Upadhyaya (pictured) during plenary for two awards Hari had received in the course of the year, also from the Crop Science Society of America. These awards were for Hari’s notable contributions – at international level – to crop science, and to plant genetic resources.

Hari is a long-term GCP Principal Investigator, working primarily on sorghum. But that is not the only crop he works on. Hari was the lead author of the joint chickpea and pigeonpea chapter in our book on drought phenotyping.

Evaluation
Unlike other GRMs where we’ve requested participants to evaluate the meeting, we did not do so this year, since this is very likely the last meeting of its kind, and the goal of the evaluation is to use participant feedback to improve future meetings. With the help of our participants, we’ve applied the lessons we’ve learnt from them through the years to arrive at what we believe to be a winning combination, balancing the diverse interests of our participants for overall improvement of their GRM experience.

 

 

 

 

 

Nov 302012
 
Photo: IRRI

Sigrid Heuer

Meet Sigrid Heuer (pictured), a Molecular Biologist and Senior Scientist at the International Rice Research Institute (IRRI). Her lively and riveting story will take us from Africa through her native Europe and on to Asia, and finally Down Under to Australia.

Origins – the African chapter
Africa holds a special and soft spot in Sigrid’s love affair with science: it was while on this continent that she realised her calling in life as a scientist – linking people doing pure research on plant genes to help plants survive and even thrive in harsh environments, with people who want to apply that knowledge to breed crops that can change the lives of millions of farmers who constantly compromise with nature to make a living.

Photo: IRRI

Fieldwork: Sigrid at a field trial for rice phosphorus uptake.

“Working as a postdoc at the Africa Rice Center in Senegal was a real life-changing experience,” Sigrid recollects with great fondness. “It’s where I found my niche, using my background in theoretical science and applying it to developing crops that could overcome abiotic stresses, and in doing so, make a real impact on people’s lives.”

Rowing further down the river: from upstream to downstream science
Sigrid was born and raised in Hamburg, Germany. She remembers wanting to be a psychologist and didn’t consider science until a few years after finishing school. After completing a biology undergraduate at Phillips University, Marburg, Germany, she returned to her home city of Hamburg to complete a Masters and PhD in plant physiology and molecular biology respectively.

“Back then, I was really involved in upstream science, fascinated in the fine details without much consideration of how such research could benefit society,” says Sigrid. “I still enjoy this form of science and really do value its purpose, but putting it into practice and focusing on the impact that it can have is what really motivates me now.”

Moving to IRRI, and meeting Pup1 and GCP
After three years in Senegal, Sigrid moved to the Philippines to join IRRI in 2003, first as a consultant then as a part-time scientist. In these early years, she was working on several projects, one of which was the GCP-funded Pup1 (rice phosphorus uptake) project.

“The project sought to identify the genes associated with phosphorus uptake in rice lines that could tolerate phosphorus-deficient soils,” says Sigrid. “It was an interesting project in which I was able to use my background in molecular biology. Little by little, I got more and more involved in the Pup1 project and after a year I was asked by Matthias Wissuwa, who was leading the project at the time, if I wanted to take it over. It was a great opportunity which I jumped at, not knowing then how challenging it would prove.”

Pup1 was the first major project I had managed. It was a playground of sorts that allowed me to learn what I needed to know about managing a project – writing proposals and reports, managing budgets and people’s time, and everything else that comes with leading a team.

The ‘root’ and  ‘command post’ where it all happens: Sigrid in the office. For the benefit of our readers, we would have credited the young artist whose colourful work graces the background below the bookshelf, but we were too polite to pry and prise out the young talent’s name, having hogged too much of Sigrid’s time already!

Learning to lead – both work and play

Over the last seven years, Sigrid has been a Principal Investigator and joint leader of the project, which has given her latitude to mature professionally, and not just in science alone. “It’s been tough but personally fulfilling,” Sigrid says, with just a touch of exhaustion.

Pup1 was the first major project I had managed. It was a playground of sorts that allowed me to learn what I needed to know about managing a project – writing proposals and reports, managing budgets and people’s time, and everything else that comes with leading a team. I was really lucky to have Matthias’ help as well as the other experienced collaborators and networks. However, the main factor that made my job a lot less stressful, was the benefit of long-term funding and support from GCP. GCP was always there, supporting us and giving us confidence even when we weren’t sure we were going to succeed.”

Persistence pays: tangible products, plus publication in Nature
In August 2012, Sigrid and her team achieved what they had set out to do seven years ago, through what Sigrid puts down to sheer persistence: their discovery of the Pup1 gene was recognised by their scientific peers and published in the highly renowned journal,  Nature.

Sigrid (3rd left) at the lab with other colleagues in the phosphorus uptake team.

“Having our paper published is really something special and personally my greatest achievement to date,” says Sigrid, but she is also quick to add that it was a team achievement, and that the achievement was in itself humbling.

“It was a double reward for persisting with the research, and with getting it into Nature. We wanted it in Nature for several reasons. To raise awareness on phosphorus deficiency and phosphorus being a limited resource, especially in poorer countries; and to draw attention to how we do molecular breeding these days, which is a speedier, easier and cost-effective approach to developing crops that have the potential to alleviate such problems.”

Sigrid hopes the article will have a lasting impression on readers, and encourage funders to continue to support projects that have such impact on the lives of end-users.

What next? Technology transfer, transitions and torch smoothly passing on…
With the Pup1 gene now found, IRRI researchers are working with breeders from country-based breeding programmes around the world to help them understand the techniques to breed local varieties of rice that can grow in phosphorus-deficient soils. They are also collaborating with other projects that wish to use the Pup1 project as a case study for phosphorous deficiency tolerance in other crops like maize, sorghum, and wheat (see an example here, that includes partners from Africa and Latin America).

Sigrid sees this next stage as a perfect time to step down from the project: she plans to move to Adelaide, Australia at the end of 2012 to lead a new project that is looking at drought and nitrogen deficiency tolerance in wheat.

“Matthias passed the baton on to me, and now I get to pass the baton on to someone else, so it’s nice. And I’ll be sure to always be around to help them too.”

Links

Sigrid’s presentation at the GCP General Research Meeting 2011

 

 

Sep 202012
 

Getting to the core of a world-favourite dessert by unravelling banana’s origin and genealogy

GCP has enabled us to lay a credible foundation, which gave us a leg-up in the intense competition that typifies the genome sequencing arena” – Angélique D’Hont, CIRAD researcher

‘A’ is also for Angélique, as you will see once you read on…

An ‘A’ to our banana team for ushering in a new era in banana genetics. But let soup precede dessert, and don’t let this worry you: stay with us because we’re still very much on the topic and focused on bananas, which offer the whole range from soup and starters, to main course and dessert, plus everything else in between, being central for the food security of more than 400 million people in the tropics: around a third each is produced in Africa, Asia-Pacific and Latin America, and the Caribbean. About 87  percent of all the bananas produced worldwide are grown by small-scale farmers.

Moving back then to soup for starters, we’re serving up our own unique blend of alphanumeric banana ‘soup’, spiced with ABCs, a pinch of 123s, plus a dash of alpha and omega. Curious about the ABCs? Look no further:‘C’ for getting to the core of ‘B’ for bananas, and an ‘A’ score for our ace genomics team that did it.

Read how GCP seeded … and succeeded, in helping open a new era in banana genetics. An achievement by itself, and an important milestone on the road to unlocking genetic diversity for the resource-poor, which is GCP’s raison d’être.

So get your travelling gear please, for time travel with a ‘midspace checkpoint’ in Malaysia.

We start in 2004, when GCP commissioned a survey of diversity with microsatellites (or SSRs, simple sequence repeats) for all mandate food crops in the CGIAR crop research Centres. The objective of that study was to make new genetic diversity from genebank accessions available to breeders.

The endpoint is opening new research avenues to incorporate genes for disease resistance, with the added bonus of an article published in Nature online on July 11 2012, entitled The banana (Musa acuminata) genome and the evolution of monocotyledonous plants.

It may not be quite as easy as the ABC and 123 that The Jacksons promise in song, but we promise you that the science is just as exciting, with practical implications for breeding hardy disease-resistant bananas. Onwards then to the first leg of this three-step journey!

(Prefer a shorter version of this story in pictures? We’ve got it! Choose your medium between Flickr and Facebook)

1) Let’s go Greek: the alpha and omega of it

Rewinding to the beginning

The proof of the pudding is in the eating: we imagine that Jean Christophe Glaszmann just has to be saying “Yummy!” as he samples this banana.

Start point, 2004: “At that time, several research groups had developed SSR markers for bananas, but there was no coordination and only sketchy germplasm studies,” recalls Jean Christophe Glaszmann (pictured), then the leader of what was GCP’s Subprogramme 1 (SP1) on Genetic Diversity on a joint appointment with CIRAD. He stepped down as SP1 Leader in March 2010, and is currently the Director of a multi-institutional research unit Genetic improvement and adaptation of Mediterranean and tropical plants (AGAP, by its French acronym) at France’s Centre de ccoopération internationale en recherche agronomique pour le développement (CIRAD) in Montpellier.

Jean Christophe continues, “The reference studies had been conducted with RFLP* markers, a very useful tool but far too cumbersome for undertaking large surveys. We mobilised Bioversity International, CIRAD and the International Institute of Tropical Agriculture for the project. The process took time, but delivered critical products.[*RFLP stands for restriction fragmented length polymorphism]

Fastforward to 2012, and gets just a little geeky…

Eight years down the road in 2012, the list of achievements is impressive, as evidenced by a suite of published papers which provide the details of the analysis of SSR diversity and describe how the data enabled the researchers to unravel the origin and genealogy of the most important dessert bananas. The origin of the predominant variety – Cavendish – suggested by the markers, involves two rounds of spontaneous hybridisation between three markedly differentiated subspecies. This scheme has been marvellously corroborated by linguistic patterns found in banana variety names as revealed in a paper published in 2011 in the proceedings of USA’s National Academy of Sciences.

But what else happened in between the start- and end-point? We now get to the really ‘sweet’ part of this bonanza for banana breeding!

It is now possible to conduct research to identify and incorporate genes for disease resistance within fertile populations that are close to the early progenitors, and then inter-cross them to re-establish sterility and obtain vigorous, disease-resistant and seedless progenies.

 2) Of bits, bananas, breeding and breadcrumbs

Threading all these bits together for breeding better bananas is akin to following a trail of breadcrumbs, in which GCP played an important facilitating role: where in the germplasm to undertake genetic recombination is one key; and then, how to expedite incorporation of disease resistance and how to control sterility – so as to first suppress it, then re-establish it – is another set of keys that are necessary for proficient breeding.

Hei Leung in the lab at IRRI.

In 2005, Hei Leung (pictured), then Leader of GCP’s Subprogramme 2 on Comparative Genomics (until June 2007) on a dual appointment with the International Rice Research Institute (IRRI), recognised that with GCP’s main focus being drought tolerance in crops, Musa (the banana and plantain botanical genus) was somewhat on the fringe. However, it was still important that GCP support the emergence of banana genomics.

Hei is currently Programme Leader of Genetic Diversity and Gene Discovery at IRRI. He remembers, “We had a highly motivated group of researchers willing to devote their efforts to Musa. Nicolas Roux at Bioversity was a passionate advocate for the partnership. The GCP community could offer a framework for novel interactions among banana-related actors and players working on other crops, such as rice. The team led by Takuji Sasaki of Japan’s National Institute of Agrobiological Science, which had vast experience in rice genome sequencing, added the scientific power. So, living up to its name as a Challenge Programme, GCP decided to take the gamble on banana genomics and help it fly.”

Angélique D’Hont, CIRAD researcher and lead author of the article published in ‘Nature’.

Through several projects, GCP helped consolidate Musa genomic resources, contributed to the establishment of medium-throughput DArT markers as well as the construction of the first saturated genetic map. Additional contributions included the first round of sequencing of large chromosome segments (BAC clones) and its comparison with the rice sequence and a detailed analysis of resistance gene analogues. All these findings have now been published in peer-reviewed journals. And while publication takes time, it still remains a high-premium benchmark for quality and validation of results, and for efficient sharing of information. It reinforces the value of collaboration, builds capacity and gives visibility to all partners, thereby providing potential new avenues for funding.

Such was the case with bananas: using a collaborative partnership framework established with the Global Musa Genomics Consortium, animated by Nicolas Roux and now chaired by Chris Town, the community developed a case for sequencing the genome. With the mentorship of Francis Quétier, contacts were made with various major players in genomics, which in the end formalised a project between France’s CIRAD and CEA–Genoscope, funded by the Agence Nationale de la Recherche and led by Angélique D’Hont (pictured) and Patrick Wincker.

GCP contributed DArT analysis for anchoring the sequence to the genetic map. But, as stressed by Angélique, CIRAD researcher and lead author of the Nature paper: “Above all, GCP has enabled us to lay a credible foundation, which gave us a leg-up in the intense competition that typifies the genome sequencing arena. We were delighted that France rolled the dice in our favour by funding this work.”

3) Musa musings on the road to and from Malaysia checkpoint

Three years down the road, the team published a description of the genome of a wild banana from Malaysia.

Jean Christophe communes with a Musa plant, perhaps musing “What’s your family history and when will you be fully grown?”

Let’s drill down to some technical facts and figures here: the Musa genome has some 520 million nucleotides distributed across 11 chromosomes, revealing traces of past duplications and bearing some 36,000 genes. While most genes derived from duplication tend to lose their function, some develop novel functions that are essential for evolution; bananas seem to have an outstanding range of transcription factors that could be involved in fruit maturity.

And while the road ahead remains long, we now have a good understanding of banana’s genetic diversity, we have genomic templates for functional studies (a whole-gene repertoire) as well as for structural studies (the chromosome arrangement in one subspecies) aimed at unraveling the genomic translocations that could control sterility in the species complex.

It is now possible to conduct research to identify and incorporate genes for disease resistance within fertile populations that are close to the early progenitors, and then inter-cross them to re-establish sterility and obtain vigorous, disease-resistant and seedless progenies.

This is undoubtedly an inspiring challenge towards unlocking the genetic diversity in this crop, which is central to food security for more than 400 million people in the tropics.

Links

 

Sep 072012
 

Preparing rice root samples (Photo: IRRI)ALL IN THE ROOTS: A plant’s roots are a marvellously multitalented organ. They act as fingers and mouths helping plants forage and absorb water and nutrients. They act like arms and legs offering a sturdy base of support so a plant doesn’t keel over. They help store food and water, like our stomach and fat cells. And in some plants, can spawn new life – we leave that to your imagination!

That is why it is of little surprise that this multitalented organ was the key to discovering why some rice lines yield better in phosphorus-poor soils, a puzzle whose answer has eluded farmers and researchers… until now.  And even better, the findings hold promise for sorghum, maize and wheat too. Please read on!

 In search of the key – The Gene Trackers
In 1999, Dr Matthias Wissuwa, now with the Japan International Research Centre for Agricultural Sciences (JIRCAS), deduced that Kasalath, a northern Indian rice variety, contained one or more genes that allowed it to grow successfully in low-phosphorus conditions.

For years, Matthias made it his mission to find these genes, only to find it was as easy as finding a needle in a genetic haystack. He teamed up with the International Rice Research Institute (IRRI), and with GCP’s support, the gene trackers were able to narrow the search down to five genes of interest.

“We had started with 68 genes and within three years, we had narrowed in on these five candidate genes. And then, one-by-one, we checked whether they were related to phosphorous uptake,” recollects Dr Sigrid Heuer, senior scientist at IRRI and leader of the team that published the discovery in Nature in August 2012.

Sigrid Heuer at a rice phosphorus uptake demonstration field in The Philippines.

“In the end we found that if a certain protein kinase gene was turned on in tolerant plants like Kasalath, then those plants would perform better in phosphorus-deficient soils.”

They named this protein kinase gene PSTOL1, which stands for Phosphorus Starvation Tolerance. “When we put this gene into intolerant rice varieties that did not have this gene, they performed better in phosphorus-deficient soils.”

The importance of phosphorus
Rice, like all plants, needs phosphorus to survive and thrive. It’s a key element in plant metabolism, root growth, maturity and yield. Plants deficient in phosphorus are often stunted.

Sigrid explains that whereas phosphorus is abundant in most soils, it is however not always easily accessible by plants. “Many soil types bond tightly to phosphorus, surrendering only a tiny amount to plant roots. This is why more than half of the world’s rice lands are phosphorus-deficient.”

Farmers can get around this by applying phosphate fertilisers. However this is a very expensive exercise and is not an option for the majority of the world’s rice growers, especially the poorer ones –the price of rock phosphate has more than doubled since 2007. The practice is also not sustainable since it is a finite resource.

By selecting for rice varieties with PSTOL1, growers will be less reliant on phosphate fertilisers.

How it works: unravelling PSTOL1 mechanics
In phosphorus-poor soils, PSTOL1 switches on during the early stage of root development. The gene tells the plant to grow larger longer roots, which are able to forage through more soil to absorb and store more nutrients.

“By having a larger root surface area, plants can explore a greater area in the soil and find more phosphorus than usual,” says Sigrid. “It’s like having a larger sponge to absorb more water.”

A rice variety — IR-74 — with Pup1 (left) and without Pup1 (right).

Although the researchers focussed on this one key nutrient, they found the extra root growth helped with other vital elements like nitrogen and potassium.

Another by-chance discovery was that phosphorus uptake 1 (Pup1), the collection of genes (locus) where PSTOL1 is found, is present within a large group of rice varieties.

“We found that in upland rice varieties – those bred for drought-prone environments – most have Pup1,” says Sigrid. “So the breeders in these regions have, without knowing it, been selecting for phosphorus tolerance.”

“When thinking about it, it makes sense as phosphorus is very immobile in dry soils, therefore these plants would have had to adapt to grow longer roots to reach water deeper in the soil and this, at the same time, helps to access more reservoirs of phosphorous .”

Breeding for phosphorus tolerance, and going beyond rice
Using conventional breeding methods, Sigrid says that her team introduced PSTOL1 into two irrigated rice varieties and three Indonesian upland varieties, and found that this increased yields by up to 20 percent.

“In our pot experiments,” she added, “when we use soil that is really low in phosphorus, we see yield increases of 60 percent and more. This will mean growers of upland rice varieties will probably benefit the most from these new lines, which is pleasing given they are among the poorest rice growers in the world.”

Read how Indonesian researchers are developing their own breeds of upland rice with the PSTOL1 gene

Sigrid also sheds light on broadening the research to other crop varieties: “The project team is currently looking at Pup1 in sorghum and maize and we are just about to start on wheat.”

Building capacity and ensuring impact
Like all GCP projects, this one invests as much time in building capacity for country breeding programmes as on research.

Sigrid and her team are currently conducting the first Pup1 workshop to train researchers from Bangladesh, India, Indonesia, Nepal, Philippines, Thailand and Vietnam. They will share molecular markers that indicate the presence of PSTOL1, techniques to select for the gene, as well as for new phosphorus-efficient varieties.

Breeding for phosphorus-efficient rice in the Philippines.

“The aim of these workshops is to take these important tools to where they are most needed and allow them to evolve according to the needs and requirements of each country,” says Dr Rajeev Varshney, GCP’s Comparative and Applied Genomics Leader. “Breeders will be able to breed new rice varieties faster and more easily, and with 100 percent certainty that their rice plants will have the gene. Within three to five years, each country will be able to breed varieties identical to those that growers know and trust except that they will now have the Pup1 gene and an improved ability to unlock and take up soil phosphorus.”

Joining hands in collaboration
This IRRI-led project was conducted in collaboration with JIRCAS and the Indonesian Center for Agricultural Biotechnology and Genetic Resources Research and Development (ICABIOGRAD) working with the Indonesian Centre for Rice Research. Other partners included: Italy’s University of Milano, Germany’s Max Planck Institute in Golm, the University of The Philippines at Los Baños, USA’s Cornell University and University of California (Davis and Riverside), Brazil’s EMBRAPA, Africa Rice Center, Iran’s Agricultural Biotechnology Research Institute, Australia’s Commonwealth Scientific and Industrial Research Organisation (CSIRO) and University of Dhaka in Bangladesh.

Links

Sigrid’s presentation at the GCP General Research Meeting 2011

Jun 202012
 

Breathing life into support services

By addressing the needs at the heart of quality agricultural research, right there on the station, GCP was the first to cotton on to a crucial missing link between researcher, research station, and support services.” – Hannibal Muhtar

Want to cut to the chase and only need the bare bones of this story? Skip over to the short version

“One thing that really energises me,” enthuses GCP Consultant Hannibal Muhtar, “is seeing people understand why they need to do the work, and being given the chance to do the how.” And so was born another wonderfully fruitful GCP collaboration. Hannibal, who describes the assignment as “a breath of fresh air,” was asked to identify, together with GCP project Principal Investigators, African research sites of ongoing or potential GCP Research Initiative projects where effective scientific research might be hampered by significant gaps in one fundamental area: infrastructure, equipment and support services.

Meet Hannibal Muhtar (Audio clip)

As at June 2012, the 19 sites selected were:

Burkina Faso – L’Institut de l’environnement et de recherches agricoles sites at :
1.  Banfora
2.  Farako-Bâ Regional Centre
Ethiopia
3.  Hawassa Agricultural Research Station
4.  The Southern Agricultural Research Institute
Ghana – Council for Scientific and Industrial Research, Crops Research Institute sites at:
5.  Kumasi
6.  Tamale
Kenya
7.    Moi University (site 1)
8.    Moi University (site 2)
9.    Egerton University (Njoro site)
10.    Egerton University (Koibatek Farmers Training Centre)
Mali – L’Institut d’Économie Rurale sites at:
11.    Sotuba
12.    Cinzana
13.    Longrola
Niger – ICRISAT site
14.    Sadore
Nigeria
15.    National Cereals Research Institute
National Root Crops Research Institute sites at:
16.    Umudike
17.    Kano
Tanzania – Agricultural Research Institute at:
18.    Naliendele
19.    Mtwara

Flashback to 2010. Picture on the left: Hannibal at a planning session at Sega, Western Kenya, with Samuel Gudu and  Onkware Augustino. Picture on the right: Similarly, at Naliendele, in Tanzania with Omari Mponda.

Flashback to 2010. Picture on the left: Hannibal at a planning session at Sega, Western Kenya, with Samuel Gudu and  Onkware Augustino. Picture on the right: Similarly, at Naliendele, in Tanzania with Omari Mponda.

Embarking on the voyage to change, storms ‘n’ all
Hannibal, armed with years of practical experience in the application of engineering sciences in agriculture and developing countries, as well as an attentive ear to the real needs of researchers, embarked on a series of visits to these research stations in 2010 and 2011, meeting with staff of all levels, departments and functions, carrying out in-depth analyses and draw up concrete recommendations for infrastructure and support service investments for each of the sites so that good-quality field evaluations (‘phenotyping’ in ‘breeder-speak) of GCP-funded projects could be conducted. Thanks to funding from GCP’s Integrated Breeding Platform (IBP), and to the openness, commitment and energy of research staff on the ground to implement these recommendations, the efforts of multiple cross-cutting partnerships across Sub-Saharan Africa are, in 2012, starting to bear fruit. But it has not all been smooth sailing, and the storms encountered along the way to reach this end goal should not be underestimated.

Weeds, wear and tear, and a walk on the wild side
The obstacles, says GCP’s Director of Research, Xavier Delannay (pictured, can often be mundane in nature – a  lack of or faulty weather stations or irrigation systems, or fields ravaged by weeds or drainage problems and in dire need of rehabilitation, for example. Yet such factors compromise brilliant research. A simple lack of fencing, Xavier and Hannibal expound, commonly results not only in equipment being stolen, but also in roaming cattle and wild animals – boars, monkeys, hippopotamus and hyena, to name but a few – stomping over precious experiment sites and posing serious threats to field staff safety. “The real challenge lies not in the science, but rather in the real nuts-and-bolts of getting the work done in local field conditions,” he explains.’’

Hannibal concurs: “If GCP had not invested in these research support infrastructure and services, then their investment in research would have been in vain. Tools and services must be in place as and when needed, and in good working order. Tractors must be able to plough when they should plough.’’

But a critical change is also needed in mindset and budgeting. ‘’The word ‘maintenance,’’’ a Senegalese partner commented to Hannibal, describing his institute, “does not exist in our vocabulary and is not a line-item on our budget.”

The problem then is not always about limited funds but rather much more on how the funds available are budgeted, excluding the all-essential support services.

Getting down to the brass tacks of local empowerment, and aiming higher
Multi-lingual and fluent in English, Arabic and French, Hannibal employed a multi-faceted customised approach, based on the needs of each site, be it sharing his tricks-of-the-trade and improvising local solutions, or guiding researchers in identifying their specific needs, as well as on where and how to request equipment, just to mention a few examples. In other cases he would teach local station managers to build and apply simple yet revolutionary tools such as land-levellers (referred to as ‘floats’ in industrial-speak), as well as row-markers for more uniform spacing between rows and plants in the field.

In addition, he would organise a training workshops in either English or French, with different content for technicians, machine operators and station managers. The dedication demonstrated by this latter group to both learn and continue these efforts after the training was particularly pertinent for ensuring the long-term sustainability of the investments.

A colourful menu of options, then, for achieving one common overarching objective, which, as summarised neatly by Xavier, is: “The effective running of local experiment stations, for facilitating local research, improving local crops, and ultimately leading to empowerment and self-reliance of local farming communities.”

“At the end of the day, it’s about achieving food security and improving livelihoods,” Hannibal emphasises. Looking back at some of the research stations that are now well-equipped and are being managed well, and the improved crop varieties being produced and projected, Hannibal highlights the “harmonious chain” triggered as a result: “Food security and better livelihoods pave way for healthy, well-fed families, and agriculture growing beyond subsistence into an economic activity,” Hannibal concludes.

Lights, curtain… ACTION!
Much like in theatre, with all the ‘props’ in place, Hannibal reports that field trials are now performing well, thanks to the all-important ‘backstage’ support service elements being in good shape. Hannibal likens the positive feedback from the partners he has worked with to “A glass of cold water, after a long day in the sun!”

And there’s a beautiful simplicity to the impacts described: “With proper infrastructure in place, and with research station staff duly equipped with the hands-on expertise and practical know-how to utilise and apply this infrastructure and training, we’re now seeing field experiments being conducted as they should be, and getting good-quality phenotyping data as a result,” says Xavier. “Moreover,” he continues, “by providing glass-houses or the capacity to irrigate in the dry season, we are enabling breeders to accelerate their breeding cycles, so that they can work all year round, rather than having to wait until the rain comes.” Sites hosting GCP projects on rice in Nigeria, as well as on sorghum and rice in Mali, are just a few examples of those enjoying off-season work thanks to new irrigation systems.

Similar good news is expected soon for cassava in Ghana and in northern Nigeria. And yet more good news: in some cases, the impacts have not been limited to the trials, or even to the research trials and stations alone, as Xavier highlights with an example from Kenya: “The establishment of an irrigation system on a plot at Koibatek Farmer Training Centre – a partner of Egerton University – yielded excellent results for chickpea experiments. We emphasised that we did not want the equipment to be ‘bracketed’ exclusively for science and experiments. So, it was also used to train staff and farmers from the local community as well. This was greatly appreciated.”

Seeing the nuts-and-bolts now firmly in place for the majority of the sites visited, Hannibal believes GCP has facilitated a pioneering approach to local capacity building: “By addressing the needs at the heart of quality agricultural research, right there on the station, GCP was the first to cotton on to a crucial missing link between researcher, research station, and support services,” he reveals.

…Another missing link…
But the job is not quite done. One crucial gap is the sensitisation of upper management – those at the helm of national research institutes and research station Directors – to support and sustain infrastructure, training and related services. In some cases, costs could be easily met by utilising a priceless asset that most institutes already have, and which they could put to greater us – land and a controlled environment.

Upper management needs to be actively on board. “A research institute should work like a good sewing machine,” says Hannibal. “All well-oiled, all parts working well, and everybody knowing what they need to do.”

In the meantime, however, results from the field suggest that researchers in GCP projects are already reaping the benefits from improved infrastructure and support services, and are already off to a good start.

The stage is therefore set: backstage and props are well primed, performance trials are acting like they should, and the ‘theatre directors’ have an eye on sustainability after GCP’s final curtain call in 2014.

So, long may the show go on, with a cautionary word, however, to continually seek ways to not only maintain but also enhance performance!

Relevant links

  • PODCASTS: You can also listen to Hannibal, by tuning into Episode 2 for the entire interview, or zooming in on your particular area of interest in the mini-podcasts labelled Episodes 2.1 to 2.7 c here.
  • Capacity building
  • Research Initiatives
  • Integrated Breeding Platform website

 

Our history

 

In Phase I (2004–2008), GCP’s focus was on exploration and discovery with an emphasis on crop diversity, while in Phase II (2009–2014), the emphasis is on application and impact, centering on breeding and services to breeders.

Phase I work covered 21 plants, while Phase II concentrates on improving nine key crops for drought tolerance :

  • beans
  • cassava
  • chickpeas
  • cowpeas
  • groundnuts
  • maize
  • rice
  • sorghum
  • wheat.

For more on our history, please visit our website

 

 

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