Dec 042014
 
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By Eloise Phipps

Think of something acid.

What came to mind… vinegar? Lemon juice? An acid remark? Chances are that you did not think of soil – the humble sods and clods we rely on to produce our food – unless, perhaps, you grow or breed crops.

It is a cruel and surprising fact that acid soils cover almost half the land that the world uses to grow food. They can be a natural result of rainfall and soil type, but are also made worse by overuse of nitrogen fertilisers. The negative impact of acid soils on annual global harvests is second only to that of drought.

We’re getting down to earth in celebration of World Soil Day, the 5th of December – and looking forward to 2015, the International Year of Soils – as we get our teeth into this Diplodocus-sized problem, and examine how research into genes shared between different species is helping plant breeders provide farmers with crops that thrive even as the pH drops.

More than half of the world’s potential crop-growing land is highly acidic. Map courtesy of Leon Kochian.

More than half of the world’s potential crop-growing land is highly acidic. Map courtesy of Leon Kochian.

Cretaceous crop split leaves common heritage – helping plants pass the acid test when soil dosages get dramatic

Did Triceratops, just like us, enjoy its daily morning breakfast cereal?

Did Triceratops, just like us, enjoy its daily morning breakfast cereal?

The cereal crops that we rely on for our staple foods are relative newcomers in evolutionary terms – just like humans ourselves. The species that are now maize, rice and sorghum all belong to the Poaceae family, or true grasses. They separated out and began to take their own evolutionary pathways roughly 65 million years ago – around the time the dinosaurs were going extinct. Before this, they had a single common ancestor, getting munched on by hungry Triceratops.

Because of this family relationship, maize, rice and sorghum still have many similar genes in common, often carrying out the same or similar functions in the different crops. And some of these functions can help plants do well when faced with the acid test.

The trouble with acid soils is not so much the pH itself, but the way it affects the availability of important nutrients. As acidity increases, aluminium becomes more soluble, giving plants an overdose that causes aluminium toxicity. One of the symptoms is stunted root growth – making it even harder for plants to reach other nutrients. Meanwhile, nutrients such as phosphorus become less available, stuck in forms that plants can’t absorb, making phosphorus deficiency another huge issue.

The consequences of subpar soils are far-reaching. A new report from the Montpellier Panel, ‘No Ordinary Matter: Conserving, Restoring and Enhancing Africa’s Soils’, finds that soil degradation affects two-thirds of arable land in Africa, and that without action it is likely to lock the continent into cycles of food insecurity for generations to come, and hamper both agricultural and economic development. Widespread soil acidity and its effect on nutrient availability are a key piece of the jigsaw; as the report observes, “In the more humid lowland areas [of Africa], soils are typically highly weathered, acidic and nutrient deficient.”

A Kenyan farmer prepares her maize plot for planting. Acid soils cover almost 90 percent of Kenya’s maize-growing area, and can more than halve yields.

A Kenyan farmer prepares her maize plot for planting. Acid soils cover almost 90 percent of Kenya’s maize-growing area, and can more than halve yields.

Collaboration and gene comparison for crops that thrive when pH dives

Fortunately, our scientists are no dinosaurs. Since 2004, crop researchers and plant breeders across the world – collaborating in several GCP projects within the Comparative Genomics Research Initiative – have been using genetic knowledge at the cutting edge of science to develop local varieties of maize, rice and sorghum which can withstand acid soils’ topsy-turvy nutrient levels. Explore our comparative genomics-themed blogposts to meet our heroes Claudia, Eva, Jura, Leon, Matthias, Rajeev, Sam, and others.

Left to right (foreground): Leon Kochian, Jurandir Magalhães (both EMBRAPA) and Sam Gudu (Moi University) examine crosses between Kenyan and Brazilian maize, at the Kenya Agricultural Research Institute (KARI), Kitale, in May 2010.

Left to right (foreground): Leon Kochian, Jurandir Magalhães (both EMBRAPA) and Sam Gudu (Moi University) examine crosses between Kenyan and Brazilian maize, at the Kenya Agricultural Research Institute (KARI), Kitale, in May 2010.

What is the advantage for breeders of knowing about a gene like PSTOL1 (in the locus Pup1), which helps rice do well under low-phosphorus conditions by encouraging it to grow longer roots? Simple. Unlike the scientists in Jurassic Park, our breeders don’t need to resurrect long-dead species to get their kicks (and fortunately, they are at lower risk of being eaten by their work!). The crops they are interested already have all kinds of useful genes hidden within them, but, as with all living things, each species is tremendously varied and diverse.

This is where genomics comes in. Instead of growing many thousands of seeds to see which plants thrive, breeders can use genetic markers to look inside the seeds to see which ones have, say, Pup1. Then they only need to grow those seeds, in order to cross-pollinate them with plants with other useful traits, making the breeding process much faster and more efficient.

Screening for phosphorus-efficient rice, able to make the best of low levels of available phosphorus, on an International Rice Research Institute (IRRI) experimental plot in the Philippines.

Screening for phosphorus-efficient rice, able to make the best of low levels of available phosphorus, on an International Rice Research Institute (IRRI) experimental plot in the Philippines. Some types of rice have visibly done much better than others.

Women farmers in India bring home their sorghum harvest.

Women farmers in India bring home their sorghum harvest.

And what makes the Comparative Genomics Research Initiative even more powerful is that it looks across related crops. Once researchers have found an acid-beating gene in one crop, they can look for similar genes in the others – turning knowledge of a single gene into multi-impact dino-mite. For example, the discovery of the SbMATE gene, behind aluminium tolerance in sorghum, spurred researchers to seek and find a similar gene in maize – which they named ZmMATE. This knowledge is now being used to breed aluminium-tolerant varieties of both sorghum and maize for Africa – and is being applied to rice too.

Maize trials in the field at our partners EMBRAPA, the Brazilian Agricultural Research Corporation. The maize plants on the left are aluminium-tolerant while those on the right are not.

Maize trials in the field at our partners EMBRAPA, the Brazilian Agricultural Research Corporation. The maize plants on the left are aluminium-tolerant while those on the right are not.

There are many more examples of the power of comparative genomics, but the real proof will be soon to come in farmers’ fields as these new, anti-acid varieties are tested and released. The world’s poorest farmers generally cannot afford other approaches to dealing with soil acidity, such as treating soil with lime or applying extra phosphorus to their fields, so the comparative approach to cousin crops promises to be a king (or should that be Tyrannosaurus rex?) among soil solutions.

A boy rides his bicycle next to a rice field in the Philippines. With acid soils affecting half the world’s arable fields, acid-beating crop varieties will help farmers feed their families – and the world – into the future.

A boy rides his bicycle next to a rice field in the Philippines. With acid soils affecting half the world’s arable fields, acid-beating crop varieties will help farmers feed their families – and the world – into the future.

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Jul 232014
 
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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.

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Mar 072014
 
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Two in one, in more ways than one
Armin Bhuiya

Armin Bhuiya

Armin Bhuiya (pictured) is a dynamic and lively young geneticist and plant breeder, who has made huge strides in tracking crucial  genes in Bangladeshi rice landraces (or traditional farmer varieties). Armin took a ‘sandwich’ approach twinning two traits  – salt and submergence tolerance – in order to boost farmers’ yields. Her quest for salt-impervious ‘amphibian’ rice has seen her cross frontiers to The Philippines, and back to her native Bangladesh with solutions that will make a difference, borrowing a leaf along the way from the mythical submarine world of Atlantis for life under water. Using cutting-edge crop science, Armin is literally recreating out-of-this-world stuff working two elements of the ancient world  earth and water – plus that commodity that was then so prized enjoying a  premium comparable to gems: salt. Read on! 

A rice heritage, and the ‘sandwich’ saga and submarine search both begin…

“My father worked at the Bangladesh Rice Research Institute (BRRI), which basically means I grew up in rice research. You could say that I was born and bred in agriculture and this inspired me to study agriculture myself,” says Armin. As a result of these early experiences, Armin started a master’s degree in 2006 on genetics and plant breeding, specialising in hybrid rice. Ever since, rice has been her religion, following in the footsteps of her father to join the Bangladesh Rice Research Institute (BRRI).

Her other defining hallmark is her two-in-one approach. Sample this: once she completed her two-in-one master’s, Armin went on to study for a PhD in the same twin areas at Bangladesh Agricultural University. Pondering long and hard on what research would be of most practical use, she asked herself “What is the need? What research will be useful for my country and for the world?” (Editorial aside: out of this world work, apparently…)

Not content  pondering  over the question by herself, her natural two-track approach kicked in. Mulling with her colleagues from BRRI, the answer, it first seemed, was to find ways to produce salt-tolerant high-yielding rice. In Bangladesh and many other parts of South and Southeast Asia, climate change is driving up the sea level, spreading salinity further and deeper across low-lying coastal rice-fields, beyond the bounds where salt-drenched terrain has long been a perennial problem. Modern rice varieties are highly sensitive to salt. So, despite the low yields and quality, farmers continue to favour hardy traditional rice landraces that can take the heat and hit from the salt. Proceeding from this earthy farmer reality and inverting the research–development continuum, Armin needed no further thinking as the farmers showed the way to go. Her role and the difference she could make was to track the ‘treasure’ genes locked in these landraces that were transferred to high-yielding but salt-sensitive rice varieties, to fortify them against salt.

But that was not all. There’s power in numbers and consulting others, harnessing the best in diversity. In comes the two-track approach again, with Armin now turning to fellow scientists again, with the reality from farmers. Upon further consultations with colleagues, yet another fundamental facet emerged that could not be ignored. Apparently, salt-impervious rice alone would not be not enough, and here’s why. Salt and tides aside, during the rainy season inland, flash floods regularly submerge the fields, literally drowning the crop. More than 20 million hectares in South and Southeast Asia are affected – including two million hectares in coastal Bangladesh alone. The southern belt of Bangladesh is particularly affected, as modern varieties are sensitive to not only submergence but also salinity. So Armin had her work cut out for her, and she now knew that for the fruit of her labour to boost rice production in coastal regions as well (two tracks again! Inland and coastal low-lying rice-lands), what she needed to do was to work on producing high-yielding, salt-impervious, ‘amphibian’ rice that could withstand not only salinity but also submarine life. In other words, pretty much rice for a latter-day real-life rendition of the mythical Atlantis.

Armin has successfully incorporated dual tolerance to salinity and submergence in the popular Bangladeshi mega-variety BR11. This will provide the ideal salt-tolerant ‘amphibian’ rice suitable for farmers in the flood-prone salty-water-drenched swaths of southern Bangladesh.

Through the door of opportunity
The opportunity that opened the door for Armin to fulfil her dream was a DuPont Pioneer postgraduate fellowship implemented by GCP. The competitive programme provides grants for postgraduate study in plant breeding and genetics to boost the yields of staple food crops. This fellowship took Armin to Filipino shores and the molecular breeding labs at the International Rice Research Institute (IRRI). Here she got what she terms a golden opportunity to work under the tutelage of Abdelbagi Ismail, a leading plant physiologist focusing on overcoming abiotic stresses. From him, Armin learnt how carry out the precise meticulous research required for identifying quantitative trait loci (QTLs).

Armin at work at the greenhouse.

Armin at work at the IRRI greenhouse in 2011.

Armin conducted her research with two different mapping populations, both derived from Bangladeshi landraces (Kutipatnai and Ashfal). She found a total of nine quantitative trait loci (QTLs) from one mapping population and 82 QTLs from another for tolerance to salinity stress at seedling stage (QTL is a gene locus where allelic variation is associated with variation in a quantitative trait). Incorporating these additional genes into a high-yielding variety will help to develop promising salt-tolerant varieties in future. She has also successfully incorporated QTLs for dual tolerance to salinity (Saltol) and submergence (Sub1) in the popular Bangladeshi mega-variety, BR11. Stacking (or ‘pyramiding’ in technical terms) Saltol and Sub1 QTLs in BR11 will provide the ideal salt-tolerant ‘amphibian’ rice suitable for farmers in the flood-prone salty-water-drenched swaths of southern Bangladesh.

I know what to do and what is needed… I am going to share what I learned with my colleagues at BRRI and agricultural universities, as well as teach these techniques to students”

Dream achiever and sharer: aspiring leader inspiring change
The Pioneer–GCP fellowship has given Armin the opportunity to progress professionally. But, more than that, it means that through this remarkable young scientist, others from BRRI will benefit – as will her country and region. “While I was at IRRI,” Armin says, “I trained myself in modern molecular plant-breeding methods, as I knew that this practical experience in high-tech research methods would definitely help Bangladesh. I know what to do and what is needed. I am going to share what I learned with my colleagues at BRRI and agricultural universities, as well as teach these techniques to students. It makes me very happy and my parents very proud that the fellowship has helped me to make my dream come true.”

Away from professional life, there have been benefits at home too, with these benefits delivered with Armin’s aplomb and signature style in science – doing two in one, in more ways than one. This time around, the approach has led to dual doctorates for a dual-career couple in different disciplines: “When I went to The Philippines” Armin reveals, “my husband decided to come with me, and took the opportunity to study for a PhD in development communications. So we were both doing research at the same time!”

While Armin’s research promises to make a real difference in coastal rice-growing areas, Armin herself has the potential to lead modern plant breeding at her institute, carry GCP work forward in the long term, post-GCP, and to inspire others as she herself was inspired – to make dreams come true and stimulate change. An inspired rice scientist is herself an inspiration. You will agree with us that Armin personifies Inspiring change, our favoured sub-theme for International Women’s Day this year.

Go, Armin, Go! We’re mighty proud of what you’ve achieved, which we have no doubt serves as inspiration for others!

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Mar 062014
 
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Restless Rebecca
Rebecca Nelson

Rebecca Nelson

I’m a mother and a wife. The idea of so many mothers not being able to feed their families, and so many children not getting the nutrients they need to reach their potential, has always pained me.” – Rebecca Nelson (pictured), Professor, Plant Pathology and Plant-Microbe Biology, Cornell University, USA

In this dispatch from the ‘frontline’, fired up and leading the charge against crop disease is ‘frontier’ scientist, restless Rebecca Nelson. Where does Rebecca’s restlessness and consequent fire come from? She says it has always bothered her that a billion people go hungry every single day

Wrestling Rebecca: feeding families one disease-resistant crop at a time
Wanting to remedy this billion-strong calamity, Rebecca has spent the last quarter century working with national and international institutes in Asia, Africa and the Americas. During this time, she has focused on understanding the ways in which plants defend themselves against diseases.

“An amazing percentage of crops are lost to pests and diseases in the developing world each year, which in turn leads to lack of food and impoverishes local economies,” she says. “These farmers can’t afford the herbicides and pesticides that developed-world farmers use to protect their crops, and those are not great solutions to the problems anyway. So it’s important to find ways to help these crops defend themselves.”

This means identifying crops with disease-resistant traits and using them to breed disease-resistant crops with long-lasting protection from a multitude of diseases.

We were really grateful that the GCP funded us so we could continue to understand and build resistance to rice blast and bacterial blight, and to connect the work on rice and maize”

Travels and travails to make a difference
After completing a PhD in zoology at the University of Washington, USA, in 1988, Rebecca spent eight years in The Philippines at the International Rice Research Institute (IRRI) and then five years at the International Potato Center in Peru. “I wanted to get out into the world and try and have a practical impact instead of doing research for the sake of research,” she says.

During her time in The Philippines, Rebecca worked on several rice disease-resistance projects. She was to continue many of these projects nine years later, as part of her GCP project – Targeted discovery of superior disease QTL alleles in the maize and rice. “We were really grateful that GCP funded us so we could continue to understand and build resistance to rice blast and bacterial blight, and to connect the work on rice and maize,” she says.

Rebecca was also delighted to involve her IRRI mentor, Hei Leung (then a GCP Subprogramme Leader for genomics), and friend, Masdiar Bustamam, of the Indonesian Center for Agricultural Biotechnology and Genetic Resources Research and Development (ICABIOGRAD). During her time at IRRI, Rebecca and her IRRI team had worked with Masdiar to establish her laboratory. “It was really pleasing to have Masdiar participate in the project and to see how far she and her lab had come since our earlier collaboration. The difference is that they now made a markedly significant contribution to the project in advancing the understanding of inheritance of rice blast and sheath blast resistance, and they developed germplasm that has really good resistance to these diseases.”

I’ve always been grateful to GCP for supporting me at that transitional stage in my career…. [I] was a relative newbie when it came to working with maize. However, I was lucky to have some really great collaborators…James helped me a lot at the start of the project and throughout. Even though our project is finished, we have teamed up on a number of other projects to continue what we started.

Tentative transition from rice to maize; shunting between class and grant-giving
Despite winning a merit-based competitive grant, Rebecca confesses she wasn’t sure GCP would accept her proposal, owing to her  then limited experience in maize research. “I’ve always been grateful to GCP for supporting me at that transitional stage in my career. I’d just returned from Peru and taken up a position at Cornell and was at that time a relative newbie when it came to working with maize. However, I was lucky to have some really great collaborators.”

Rebecca (left) on a field visit to Kenya in September 2006. On the left is John Okalembo of Moi University, with James Gethi behind the camera.

Rebecca (left) on a field visit to Kenya in September 2006. On the left is John Okalembo of Moi University, with James Gethi behind the camera.

One such collaborator, who Rebecca is thankful to have had on her project, was James Gethi, of the Kenya Agricultural Research Institute (KARI), and a leading researcher in Kenya. At the time, James was a recent Cornell graduate who was returning home to help bolster his nation’s crop-research capabilities. “James helped me a lot at the start of the project and throughout. Even though our project is finished, we have teamed up on a number of other projects to continue what we started.”

At Cornell, Rebecca oversees her own laboratory and still finds time to teach a class on international agriculture and rural development. She also serves as scientific director for the McKnight Foundation’s Collaborative Crop Research Program (CCRP), a grants programme funding agricultural research in developing countries.

Growing up with science…and a moderate Rebecca rebellion!
As our conversation draws to a close, Rebecca reveals she is currently skyping from the bedroom she grew up in, in Bethesda, Maryland, half an hour from downtown Washington DC, USA. “I’m down visiting my parents before I jet off to West Africa tomorrow,” she says where she is carrying out her CCRP commitments.

Rebecca credits her parents for encouraging her scientific inquisitiveness and determination to aid those in need. “Both of my parents are physicians, as is my younger brother. I thought I was a rebel with my interest in agriculture, but my younger sister is a farmer and agroecologist, so I guess we’re both straddling agriculture and science,” Rebecca says with a laugh.

“In all honesty though, my parents encouraged all of us to follow what we were fascinated by and passionate about, and for me and my sister, that was agriculture. We reared goats in our suburban backyard, dissected animal road-kills on the kitchen table and even turned the  family swimming pool into a fish-pond because we wanted to learn about fish farming!” Rebecca recollects with great fondness.

I still get a kick out of trying to understand the biology of disease resistance and to try to help develop disease-resistant crops, which will help alleviate the fallout from crop failure and subsequent food shortages in developing nations”

Wife and mum, manager and mentor, and what gives Rebecca a kick
Rebecca says she and her journalist husband, Jonathan Miller, try to encourage their two sons, William and Benjamin, in the same manner. She also says she uses a similar theory as a mentor. “I love interacting with the young talent and I like to think I’ve grown as a person the more that I’ve evolved as a manager and mentor.”

Although she spends most of her time at her desk or on a plane or in a meeting room, Rebecca is always keen to jump back into the field and familiarise herself with the science she is overseeing. “I still get a kick out of trying to understand the biology of disease resistance and to try to help develop disease-resistant crops, which will help alleviate the fallout from crop failure and subsequent food shortages in developing nations.”

Links

 

Feb 212014
 
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Steaming rice bowl

Steaming rice bowl

What’s the latest from ‘GCP TV’? Plenty! With a world-favourite – rice – featuring high and hot on the menu.

Now serving our latest news, to tease your taste-buds with a tantalising and tingling potpourri of memorable cross-continental rice flavours, all captured on camera for our viewers…

Our brand-new series on YouTube serves up a healthy seven-course video feast inviting our viewers to sink their teeth into rice research at GCP.

First, we settle down for a tête-a-tête in the rice research kitchen with chef extraordinaire, Marie-Noëlle Ndjiondjop, Principal Investigator (PI) of GCP’s Rice Research Initiative in Africa, and Senior Molecular Scientist at Africa Rice Center. Target countries are Burkina Faso, Mali and Nigeria.

Photo: A Okono/GCP

Marie-Noëlle Ndjiondjop

Starters, palate and pocket
Marie-Noëlle opens the feast with a short but succulent starter, as she explains succinctly in 30 seconds just how rice is becoming a staple in Africa. In the second course, Marie-Noëlle chews over the questions concerning combatting constraints and boosting capacity in rice research in Africa.

The third course is pleasing to the eye, the palate and the pocket! Marie-Noëlle truly sells us the benefits of molecular breeding, as she extolls the virtues of the “beauty of the marker”. Why should you use molecular tools? They’ll save you time and money!

Rice as beautiful as the markers Marie-Noëlle uses in molecular breeding

Wherefore art thou, capacity building in rice research in Africa?
The Shakespearean language alludes to the why of capacity building in Africa, as does video episode number four, which also tackles the what of this fourth dish in our banquet. Course number five offers the viewer a light look at how capacity building in Africa is carried out.

In the 6th course, Marie-Noëlle takes us out of this world and into MARS: she teaches us that ‘two are better than three’, as she explains how the novel bi-parental marker-assisted recurrent selection (MARS) method is proving effective when it comes to duelling with drought, the tricky three-headed monster comprising physiological, genetic and environmental components.

Blooming rice in the field

Of stars and scoundrels
The 7th and final course offers us a riveting tale of heroes and villains, that is, many heroes and a single villain! Our rice raconteuse, Marie-Noëlle, praises the power of the team, as a crew from cross-continental countries come together, carefully characterise their combatant (drought), before striking with environment-specific drought-tolerant varieties! AfricaRice’s project partners are Burkina Faso’s Institut de l’environnement et de recherches agricoles (INERA); Mali’s Institut d’économie rurale (IER); and Nigeria’s National Cereals Research Institute (NCRI). Collaborators are France’s Centre de coopération internationale en recherche agronomique (CIRAD); the International Center for Tropical Agriculture (CIAT); and the International Rice Research Institute (IRRI).

We hope these tasty teasers are enough to whet your appetite – you can savour each of the courses individually à la carte, or, for those with a daring desire to try the ‘all you can eat’ buffet for true rice gourmets, all seven courses are presented as a single serving on our YouTube channel.

Jonaliza Lanceras-Siangliw

Jonaliza Lanceras-Siangliw

Tastes from Asia
To further please your palate with our rice bowl of delights, our next stop is Asia. We are  pleased to offer you the Asian flavour through a peek into the world of molecular rice breeding in the Mekong region. Our connection to this project is through a GCP-funded capacity-building project entitled A Community of Practice for strengthening rice breeding programmes by using genotyping building strategy and improving phenotyping capacity for biotic and abiotic stresses in the Mekong region led by PI Jonaliza Lanceras-Siangliw, of the National Center for Genetic Engineering and Biotechnology (BIOTEC), Thailand (see project poster, and slides on a related drought-tolerance project led by Boonrat Jongdee). BIOTEC’s partners in the Mekong rice breeding CoP are the Cambodian Agricultural Research and Development Institute (CARDI); LAO PDR’s National Agricultural and Forestry Research Institute (NAFRI);  Myanmar’s Department of Agricultural Research (DAR); and Thailand’s Kasetsart University and Ubon Ratchathani University). The video also features former GCP PI, Theerayut Toojinda (BIOTEC) whose project was similarly entitled The ‘Community of Practices’ concept applied to rice production in the Mekong region: Quick conversion of popular rice varieties with emphasis on drought, salinity and grain quality improvement.

BIOTEC

Boonrat Jongdee

Shifting gears: golden oldie
If all of this talk of eating has been a little overwhelming, we also offer you the perfect digestif: a ‘golden oldie’ in terms of GCP video history showing a 2012 BBC interview with former GCP PI, Sigrid Heuer, then at the International Rice Research Institute (IRRI), who explains how her project isolated the rice root-enhancing gene PSTOL1. Bon appétit!

 

Might you still have a corner of your mind yearning for more material on rice research? If so, check out the following:

  • Our lip-smacking selection of rice-related blogposts
  • A gorgeous gallery of PowerPoint presentations on rice research (SlideShare)
  • Check out our one-stop Rice InfoCentre for all things rice and nice, that we have online!

 

Dec 122013
 
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Down memory lane with Masdiar Bustamam, from generation to generation

Masdiar Bustamam

In some circles, Masdiar Bustamam (pictured right) is a mother figure of molecular breeding in Indonesia. In a marathon career spanning 37 years as a horticulturist and agricultural researcher, she helped develop and nurture the practice at the Indonesian Center for Agricultural Biotechnology and Genetic Resources Research and Development (ICABIOGRAD).  Staying with the marathon metaphor, this quote from a celebrated middle- and long-distance Kenyan champion runner, Kipchoge Keino, is very apt: “This life we have is short, so let us leave a mark for people to remember.”

Back to Masdiar: having retired in early 2012, we were recently lucky enough to gain a rare insight into Masdiar’s life, and to witness the mark she has already made, by simply tagging along when she checked in on two of her ICABIOGRAD charges and mentees whose PhD studies were supported by GCP – Wening Enggarin and Joko Prasetiyono. At ICABIOGRAD, Wening and Joko have both taken the torch from Masdiar for GCP projects, as well as for other projects.

She was the best teacher for me … instilled in me a spirit to never lose hope in the research I’m doing – Joko

She was a great role model… Her persistence and positive can-do nature was exactly what I needed as a young researcher … to not just offer me assistance in my work but also in life and religion. For me, she has become a second mother  – Wening

… That project really helped us out a lot and we are grateful to GCP  for recognising the potential in us and supporting it – Masdiar

Here’s more of what Masdiar (and her charges) had to say as we tagged along, and chatted her up…

Tell us about your early life
I grew up and lived in West Java for most of my life. My father was a farmer and my mother a housewife. I was their first of five children.

I went to Andalas University in Padang and graduated with a Bachelor in Biology in 1974. After graduating, I worked as a staff researcher at a local horticulture research institute focusing on pests and diseases, particularly fungi in tomato soils. I was lucky early in my career to have opportunities to visit research institutes in The Netherlands, Japan and USA, all of which enhanced my skills. While in USA, I completed my Masters in rice blast disease – a fungus-related disease, which severely hampers rice yields in Indonesia, and all around the world.

After my time in USA, I accepted a position at the International Rice Research Institute (IRRI) in The Philippines. This was the start of the second phase of my career, in which I began to focus on molecular biology. When I returned from The Philippines, I realised that we needed to improve our capacity to use molecular markers for breeding, which led me to take a job at ICABIOGRAD.

Setting up a lab – GCP lends a hand
When I first started at ICABIOGRAD we had empty benches. It took a lot of time and money to fill them with the equipment we have today. Rebecca Nelson from Cornell University in USA provided us with a lot of support in getting us started. We were involved in one of her GCP projects for two years working on blast resistance in rice.

We were also working on another GCP project led by Abdelbagi Ismail studying phosphorus-deficiency tolerance in rice too, dubbed the Pup1 project. Joko was actually my PhD student for that project and did a lot of the work.

Selecting Pup1 lines in farmers' fields in Sukabumi, West Java, in 2010. L–R: Masdiar Bustamam, Tintin Suhartini and Ida Hanarida Sumantri.

Selecting Pup1 lines in farmers’ fields in Sukabumi, West Java, in 2010. L–R: Masdiar Bustamam, Tintin Suhartini and Ida Hanarida Sumantri.

Both Rebecca and Adbdelbagi helped me draft a proposal to GCP in 2007 for a project to enhance our capacity in phenotyping and molecular analysis to develop elite rice lines suitable for Indonesia’s upland regions. We had the understanding to do the science, but needed to enhance our facilities to carry it out.

That project really helped us out a lot and we are grateful to GCP  for recognising the potential in us and supporting it.”

GCP recognised the need for such a project as many of Indonesia’s brightest researchers were leaving the country because of the lack of suitable facilities, and so funded the two-year ICABIOGRAD-defined capacity-building project. The grant covered – among other areas – intensive residential staff training at IRRI; PhD student support, which allowed Wening to complete her PhD; infrastructure such as a moist room, temperature-controlled centrifuge apparatus, computers and appropriate specialised software; and blast and inoculation rooms.

Writer’s note: The tailor-made grantee-driven capacity-building project above was a cornerstone of  GCP Phase I’s capacity-building strategy, and was dubbed ‘Capacity building à la carte’. With this historical note, we take an interlude here, to tour the facilities Masdiar has mentioned above.

Our first stop is the Rice Blast Nursery…

....Front view...

….Front view…

...side view...

…side view…

 

 

 

 

 

 

 

 

... and a close-up on the sign in the side view.

… and a close-up on the sign in the side view.

 

Next, we visit the Inoculation and Moist Rooms…

 

Inoculation and Moist Rooms

Inoculation and Moist Rooms…

 

Close-up

…and a close-up on the sign at the front.

 

 

 

 

 

 

 

After our tour of the facilities, Masdiar resumes her story: “That project really helped us out a lot and we are grateful to GCP  for recognising the potential in us and supporting it so that researchers like Wening bloom and blossom, now and into the future,” says Masdiar glowingly of one of her mentees and successors.

I’m proud of how they have matured and I’m really looking forward to when they and their teams produce new rice varieties, from the facilities I helped establish, that will help the farmers…I sacrificed what I enjoyed doing for a challenge whose benefits I recognised for my country.”

Mission-driven researcher, nurturer and mentor, all rolled into one
For Masdiar, it wasn’t work, but rather a passion and a hobby. “Throughout my career, I always enjoyed research, especially in plant pathogens,” she remembers. “Working with biotechnology was difficult because I didn’t have a background in the area. I sacrificed what I enjoyed doing for a challenge whose benefits I recognised for my country.”

Photo: ICABIOGRAD

From generation to generation: Masdiar (2L) drops in on her charges and torch-bearers at ICABIOGRAD’s Molecular Biotechnology Lab. L–R: Wening Enggarini, Masdiar Bustamam, Tasliah Zulkarnaeni, Ahmad Dadang and Reflinur Basyirin.

In the later half of her career, Masdiar recollects how she enjoyed training and mentoring younger researchers like Joko and Wening. “I’m proud of how they have matured and I’m really looking forward to when they and their teams produce new rice varieties, from the facilities I helped establish, that will help the farmers.”

Both Joko and Wening attest that Masdiar’s support and supervision were vital for their professional development and consequent career advancement. “She was the best teacher for me. She taught me how to manage a project, how to forge international collaborations, and how to write a good publication,” remembers Joko. “She also instilled in me a spirit to never lose hope in the research I’m doing.”

“She was a great role model for me!” exclaims Wening proudly. “Her persistence and positive can-do nature was exactly what I needed as a young researcher who was just starting a career. Even more so was her ability to take time out of her busy day to not just offer me assistance in my work but also in life and religion. For me, she has become a second mother  in this life. I’m blessed to be so lucky!”

Clearly, Masdiar has made her mark, leaving a cross-generational living legacy in molecular breeding embodied in these young researchers.

Links

  • Masdiar’s project report, with a picture of the blast nursery under construction (p 156 in this PDF)
  • Photo-story on Facebook
  • Rebecca Nelson’s project, Targeted discovery of superior disease QTL alleles in the maize and rice genomes (p 16 in this PDF)
  • GCP’s capacity building

 

Jan 232013
 
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Abdelbagi Ismail

 I was forever inquisitive as to how things grew, and questioning when they didn’t grow well. I think it’s what got me interested in plant science.”
– Abdelbagi Ismail, Plant Physiologist and Principal Scientist, International Rice Research Institute.

Today, we talk to Abdel. His riveting voyage in plant science starts on the bountiful banks of the Nile, before we sail on to Asia’s ricelands.  We’ll make a short stopover in USA for cowpeas and drought in between,  then proceed to to our main meal of rice, spiced and seasoned with a strong dash of salt-and-P.

It’s not just about food, but also family: you’ll  get to meet a sister Challenge Programme along the way. Intrigued? We hope so, so please do read on

‘A’ for Abdel and agriculture – an early passion for plants
From a tender age, Abdel was fascinated by agriculture.

Growing up on a small family farm backing onto the banks of the Nile in the Northern State of Sudan, he helped his parents in tilling the land, sowing and harvesting.

Abdel reminisces, “It was a relaxing paradise with all types of fruit growing around you year-round. Working and living on a farm, I was forever inquisitive as to how things grew, and questioning when they didn’t grow well. I think it’s what got me interested in plant science.”

Armed with a Bachelor’s and Master’s in Agricultural Sciences (agronomy, crop production, water relations) from the University of Khartoum, Sudan, Abdel moved to the University of California, Riverside, USA, for a PhD on drought tolerance in cowpeas.

“It was the first time I had ever left Africa, and it was a real eye-opener,” Abdel recalls. “It was a fantastic new page in my career too, as I was working with world-class professors and mentors. I chose to work on cowpeas because it is a hardy crop that can be grown in dry conditions which were – and still are – becoming more prevalent in sub-Saharan Africa.” (you can take a sidetrack here, to see our research on cowpeas)

 What interests me is how some societies have survived, and, in some cases, flourished because they invested in improving their plants and crops to adapt and adjust to weather adversities.”

Navigating away from the Nile, and discovering his niche
For this native son of the Nile, this move was a watershed. It marked the start of a dedicated – and still ongoing – career quest to understand how plants can adapt to better tolerate extreme environmental stresses such as higher and lower temperatures, too much or too little water, salinity, and nutrient imbalances.

“Abiotic stresses have had, and continue to have, a major impact on human life, with some societies disappearing altogether because of changes in soils or climate,” says Abdel. “What interests me is how some societies have survived, and, in some cases, flourished because they invested in improving their plants and crops to adapt and adjust to weather adversities.”

From time immemorial, the communities around the Nile where Abdel spent his childhood are a prime example of this flourishing against adversity.

IRRI beckons, and nurtures
In 2000, Abdel accepted a position at the International Rice Research Institute (IRRI) in The Philippines.

Abdel inspects cyclone-damaged rice in Isladi Village, southern Bangladesh.

“I saw it as an opportunity to convert knowledge and scientific discoveries into resources that could help needy farmers,” explains Abdel.

Abdel confesses that when he joined IRRI, his intention was to stay for a short stint and then move on. But as he became more involved in his work, he felt IRRI offered him the best opportunity to build his career, and to contribute to global food-security issues.

“I’ve been here for 12 years now. IRRI really is a great place to grow as a person and a researcher, and to learn how to become a leader.”

Having GCP provide ongoing funding and support for public institutions to conduct a long-term project has been pivotal to the success of the project. It has given us all the security we need to focus on conducting the complex research required…”

Trailblazing for GCP : a much-needed dash of ‘salt-and-P’
In 2004, Abdel proposed a collaborative project between nine different research organisations, across seven countries, to improve salt tolerance and phosphorus uptake efficiency in rice. The work was funded by a sister CGIAR Challenge Programme on Water and Food (CPWF).

This work caught – and held – GCP’s attention, because it sought to overcome a problem that negatively affects the lives of tens of thousands of rice growers around the world. The two resultant GCP-funded IRRI-led projects involved partners from Bangladesh, India, Indonesia, Vietnam and USA’s University of California, Davis. Globally, more than 15 million hectares of ricelands are saline, and more than one-third of all ricelands are phosphorus-deficient, hitting poor communities hardest.

In the nine years since, and together with his colleagues and partners, Abdel has developed the proposal into a productive and coherent suite of interconnected projects: he has managed and overseen most of the progress made during the discovery of the genes associated with salinity tolerance (Saltol) and phosphorus uptake (Pup1), and their insertion into well-known rice varieties that farmers in Bangladesh, Indonesia and The Philippines know and trust.

It’s all about rice: salt tolerance (Saltol) ‘meets’ phosphorus uptake (Pup1) in Bangladesh. Abdel is on the extreme right. Next to him is Sigrid Heuer, Principal Investigator of the ‘Pup1’ work.

Keeping the faith, and going where no rice has gone before…
A long-term horizon helps, since, just like art, science cannot be hurried: “Having GCP provide ongoing funding and support for public institutions to conduct a long-term project has been pivotal to the success of the project,” Abdel emphasises.

“It has given us all the security we need to focus on conducting the complex research required to advance our knowledge about these genes, then breed and develop popular varieties containing then. In some cases, we have developed lines with doubled yields, and grown rice in areas where it has never been grown before because the land was too saline.”

For Abdel, such achievements are heartening as they provide farmers with greater food and income security, which in turn improves their and their community’s livelihoods.

“It brings a smile to my face whenever I think about how our work helps to produce higher-yielding crops for poverty-stricken countries whose farmers often can only afford to grow one crop per year,” says Abdel sincerely.

Abdel continues to build upon, and has even employed, partners he has met through the GCP project…”We want to improve their capacity to take up new breeding techniques, such as the use of molecular markers, which can reduce the time it takes to breed new varieties from six to 10 years to two to three years…”

Continually building on the best
So what’s in store for the future?

Having discovered the Saltol gene and developed experimental lines, his team is now training breeders from country breeding programmes on how they can successfully breed for salt tolerance and tolerance of other abiotic stresses using their own popular varieties, thereby fortifying popular varieties with these much-needed tolerance traits.

“We want to improve their capacity to take up new breeding techniques, such as the use of molecular markers, which can reduce the time it takes to breed new varieties from six to 10 years to two to three years,” reveals Abdel. “This will allow them to breed for crops quicker, in response to ever-changing and extreme climate conditions.”

As for his other projects with IRRI, Abdel continues to build upon, and has even employed, partners he has met through the GCP project to help him with his Stress tolerant rice for Africa and South Asia (STRASA) project.

GCP helped IRRI attract support from other funders…”

Going further, faster, together… five and counting, still learning, and the future looks bright
STRASA is almost five years old and has another five years left to run.

“GCP helped IRRI to attract additional support from other funders, such as the Bill & Melinda Gates Foundation, to start STRASA, which seeks to support the development and distribution of stress-tolerant varieties in Africa and South Asia,” Abdel explains.

Abdel’s parting words? “I’m still committed to understand how plants can be manipulated to adapt to, and better tolerate, extreme environmental stresses, which seems  more feasible today than it has ever been before.”

Links

Dec 212012
 
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I’ve always enjoyed my job, particularly teaching students and young researchers, but this project has made me think about how I can do more practical science.” – Zeba Seraj, Biochemistry and Molecular Biology Professor, University of Dhaka, Bangladesh

Zeba Seraj

Growing up with a botanist as a father, Zeba Seraj was nurtured to look at plants in a scientific light. But at one stage in her life, she took a different fork on the road: she was more interested in rat livers and cow eyes, before becoming a ‘late bloomer’ in applied science and molecular plant breeding, which is her current niche.

Taking that fork: rats seduced, cows made eyes, but both lost…
Having completed her Undergraduate and Master’s in Biochemistry at the University of Dhaka, Bangladesh, during the 70s and 80s, she moved to Scotland for a PhD at the University of Glasgow. After being persuaded that molecular biology and recombinant DNA technology were not likely to be too different in animals and plants, she focused on the separation of nuclear proteins involved in post-transcriptional processing in the rat liver system.

“I then went on to work as a postdoc at the University of Liverpool, UK, for 18 months, where I worked on a bovine retina cDNA [complementary DNA] library,” Zeba recalls. “I was exposed to a number of recombinant DNA techniques and was pleasantly surprised to find DNA much easier to work with compared to proteins! I enjoyed it, but when I returned to the Bangladesh, there was no work in that field, so I turned to plants.”

The rise of rice, propelled by ‘Petrra’ project and petri dish
Back at her old University, one of Zeba’s first projects was working on salt tolerance in rice which allowed her to set up plant tissue culture facilities and establish a modest molecular biology laboratory. Zeba thereafter worked with the International Rice Research Institute (IRRI) and the Bangladesh Rice Research Institute (BRRI) on the Petrra project (poverty elimination through rice research assistance). The project was funded by the Department for International Development, UK. Meanwhile, she also spent a couple of months in the laboratory of the illustrious Dr John Bennett at IRRI, learning the latest technology in DNA markers and polymerase chain reaction (PCR) technology. This inital work would, in a way, lead her to GCP.

Meeting GCP, and banking on potential
Zeba joined the GCP community in 2005, working on the rice Saltol (salt tolerance) project. She was a focal collaborator in Bangladesh for this IRRI-led project that aimed to revitalise marginal ricelands by discovering and breeding into popular rice varieties ‘survival’ genes to enable rice to not only survive but also thrive on saline or phosphorus-poor soils.

“We were introduced to the project through the Principal Investigator, Abdel Ismail,” recalls Zeba. “Our lab was not very modern, but we did have all the facilities to do marker work, as well as a firm grasp on the theory, so IRRI and GCP must have seen potential in us.”

 …doing the research helped me understand the practical application better… It was a real eye-opener.”

Transiting from theory to practice
After 15 years of working as an associate professor and professor at the University of Dhaka (DU), mainly nurturing young biochemists, Zeba was re-energised by the thought of working on such a practical project that would have a direct impact on her country’s food security, and on its farmers’ livelihoods.

In the background, genotyping in progress at the Department of Biochemistry and Molecular Biology, University of Dhaka. In thef oreground, student– supervisor consultations. Pictured (left to right) are: Zeba I Seraj, Roman, Adnan, Sarwar, Debashis,Rabin, Dost, Mishu, Shamim and Rejbana.

Nearly one million hectares along the Bangladesh coast are affected by varying degrees of salinity which has severely limited the introduction of modern high-yielding rice varieties, as few of these are saline-tolerant. Given Bangladesh’s high population, farmers need as bountiful yields as possible, and minimum risk of failure.

“After reading and teaching theory for so long, it was really exciting to actually put it into practice and work towards a practical outcome,” says Zeba.

“Actually doing the research helped me understand the practical application better too. It was a real eye-opener.”

 Using molecular markers allowed us to at least halve the time it would take to release stress-tolerant rice.” 

Gaining time: the ‘miracles’ and ‘magic’ of molecular makers
Zeba’s lab was responsible for the molecular evaluation and selection of rice lines bred by BRRI for insertion of the genomic region containing Saltol (discovered to confer salt toleranceby the previous IRRI-led GCP-funded project).

Md Sazzadur Rahman of BRRI assesses progress on a salt-tolerant rice variety in the field.

“We collected leaf samples from the BRRI-bred lines which were a combination of popular rice landraces and a Saltol donor.” explains Zeba ‘Landraces’ is ‘breeder-speak’ for varieties grown by, and popular with, farmers, but not necessarily improved by selective scientific breeding. Zeba continues, “We then used molecular markers which would indicate the presence of the Saltol genomic region.”

“The information we gathered guided the breeders at BRRI to select rice plants with the Saltol region. Selected plants were then further analysed with markers, to maximise the presence of popular alleles,” she adds. Allele is one of two, or more, forms of a gene – the alternative form of a gene responsible for a trait producing different effects.

“Using molecular markers allowed us to at least halve the time it would take to release stress-tolerant rice,” Zeba reveals.

 I will be the happiest person on earth the day they release the new lines, knowing that I’d helped to make a difference.”

Seven years on, what next?
Zeba is grateful that she and her lab were active partners in GCP projects for seven consecutive years: first in the IRRI-led project in 2005 to 2009, then in a follow-up supplementary capacity-building DU-led project from 2010 to 2011, for which Zeba was the Principal Investigator.

Nirmal Sharma and Jamal emasculate the first backcross population of a crosscombination for a second backcross at BRRI

“I don’t think we could have done the work without the various GCP networks. Several times in the project we would lag behind and they’d offer us support to get us back on track,” says Zeba. “They also instilled in us the importance of proper data management, and we have now implemented their system to collect, store and report data for all of our projects. We also now have all the equipment and processes in place, meaning that we’re now able to accommodate similar projects, now and into the future.”

Personally Zeba feels the project has given her a new direction in her career that she’s keen to further explore. “I’ve always enjoyed my job, particularly teaching students and young researchers, but this project has made me think about how I can do more practical science,” confides Zeba.

As for the Saltol project, she is keeping a close eye on the application waiting for the news of high-yield salt-tolerant lines becoming accessible to all Bangladeshi rice farmers.

“I will be the happiest person on earth the day they release the new lines, knowing that I’d helped to make a difference.”

Links

  • More on Zeba Seraj on page 40 here
  • The road behind us: read on the early days (2005/2006) of the rice salt-tolerance work:
    • on pages 36–39 here
    • on pages 28–30 here
    • on page 6 here
  • Profile: Abdel Ismail, Principal Investigator of the salt tolerance project

 

Nov 302012
 
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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 072012
 
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Joko infront of his office at ICABIOGRAD’s Molecular Biology Division.

Indonesian upland rice growers can expect to receive improved varieties that thrive in phosphorus-poor soils within a few years, thanks to the hard work of their national breeding programmes.

Joko Prasetiyono is a proud Indonesian researcher who loves rice.

“I don’t know why. I just love researching ways to improve it so it grows and yields better. I also I love to eat it,” says Joko with a laugh.

Having worked as a molecular breeder, concentrating solely on rice for 17 years at the Indonesian Center for Agricultural Biotechnology and Genetic Resources Research and Development (ICABIOGRAD), one would expect a different reaction. But Joko says he’s as interested in the little white grain as much as when he started as an undergraduate with ICABIOGRAD.

And why wouldn’t he be when he and his team are contributing to research that has just been published in Nature and is set to reduce fertiliser application and improve rice yields in Indonesia and the world over by 20 percent!

Improving Indonesian varieties, no genetic modification

Farmers often use phosphate fertilisers to aid in growing rice in these areas, but this option is often too expensive for Indonesian upland growers.

The project has found plants that have a Pup1 locus (a collection of genes), with the specific gene PSTOL1, are able to tolerate phosphorus-deficient conditions and produce better yields than those not suited for the conditions. An Indian rice variety, Kasalath, was one such.

“We are breeding rice varieties that we know have a Pup1 locus and subsequent PSTOL1 gene in them with Indonesian varieties that are suited to Indonesia’s growing systems,” explains Joko.   

Partnering with the International Rice Research Institute (IRRI), ICABIOGRAD and their partner the Indonesian Center for Rice Research (ICRR) have improved the phosphorus tolerance of Indonesian rice varieties Dodokan, Situ Bagendit and Batur.

“The new plants we are creating are not genetically modified; just bred using smarter breeding techniques,” says Joko. “The aim is to breed varieties identical to those that farmers already know and trust, except that they will have the PSTOL1 gene and an improved ability to take up soil phosphorus.”

Joko says that these varieties are currently being tested in field trials and it will take another 2–3 years before Indonesian farmers will have a variety that will yield as well if not better, needing 30–50 percent less fertiliser.

Evolving Indonesian plant research 

ICABIOGRAD team selecting breeding material in 2010. L-R: Masdiar Bustamam, Tintin Suhartini and Ida Hanarida.

GCP is as much about its people and partnerships as its research and products. ICABIOGRAD benefited from a GCP capacity-building grant in mid-2007 to enhance the institute’s capacity in phenotyping and molecular analysis. The grant covered, among other areas, intensive residential staff training at IRRI; PhD student support; infrastructure such as a moist room, temperature-controlled centrifuge apparatus, computers and appropriate specialised software; and  a blast innoculation room. These capacity-building activities were coordinated by Masdiar Bustamam who has since retired, but was then a Senior Scientist at ICABIOGARD.

But coming back to Joko and the PSTOL1 work, Joko started on this project in 2005 as a GCP-funded PhD student at Bogor Agriculture University, Indonesia. He is grateful to be part of a transnational project, which has offered him technical support that he would not otherwise have been able to receive through ICABIOGRAD alone.

IRRI visits ICABIOGRAD in 2009. L-R: Matthias Wissuwa, Sigrid Heuer (both IRRI), Masdiar Bustaman (ICABIOGRAD) and Joong Hyoun Chin

Joko believes the experience of working with IRRI, as a joint partner on this project, will leave an important, and lasting, legacy for researchers at ICABIOGRAD and ICRR. The partnership has also challenged the two local institutes to broaden their horizons past their borders.

“IRRI is teaching us how to use marker-assisted selection and we [ICABIOGRAD and ICRR] are just as busy identifying phosphorus-deficient hotspots in upland areas, choosing the best Indonesian recipient rice varieties for the gene, conducting the breeding and phenotyping testing,” he clarifies.

Breeding for sustainability

The ultimate goal of this project is to help Indonesian growers use marginal land.

Over half the world rice lands are deficient of ‘plant-available’ phosphorus, and Indonesia is no different. Joko explains that while there is plenty of phosphorus in the soil, plants are not able to access it.

“Other minerals in the soil like aluminum, calcium and iron are bound to phosphorus, shielding it from plants roots so they can only absorb a fraction of it.”

Field test of Pup1 lines at Taman Bogo , Indonesia.

In most countries, farmers apply phosphate fertilisers to their crops to combat this deficiency. For Joko this is not a sustainable approach for a lot of Indonesia’s farmers because the fertilisers are expensive and costs will continue to rise as phosphate supplies dwindle.

“Our approach is a lot more sustainable and cost-effective than applying fertiliser. We’ll breed these new plants for phosphorus-poor soils to produce more roots so they can find more phosphorus. The more phosphorus they find, the more of it they can absorb.”

Joko hopes these new plants will help farmers on marginal lands to obtain decent yields without having to spend money on expensive phosphate fertilisers.

“It’s great that our work has been recognised by Nature for publication, but what we really want is to help rice growers here in Indonesia and around the world.”

Links

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