Jan 082015
 
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Welcome to Brazil! Journey by road six hours northwest from Rio de Janeiro and you’ll arrive to Sete Lagoas,  a city whose name means ‘Seven Lagoons’ in Portuguese. Although cloistered in farmlands, the city is largely a commercial centre, but also the seat of Embrapa Milho e Sorgo, the nerve centre of EMBRAPA’s maize and sorghum research, and so could pass for the ‘sede’ (Portuguese for headquarters) of the these two cereals. EMBRAPA is the Portuguese acronym for Empresa Brasileira de Pesquisa Agropecuária; the Brazilian Agricultural Research Corporation. EMBRAPA is a GCP Consortium member, and contributed to the proposal that founded GCP.

Photo provided by J MagalhãesJurandir Magalhães (pictured), or Jura, as he likes to be referred to in informal settings such as our story today, is a cereal molecular geneticist who has been working at the Embrapa Milho e Sorgo centre since 2002. “The centre 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 qualities are exactly what appeal to GCP, which has supported Jura as a Principal Investigator since 2004. Beyond science and on to governance and advisory issues, Jura is also EMBRAPA’s representative on the GCP Consortium Committee.

Home and away, on a journey of discovery in sorghum
Hailing from Belo Horizonte, Minas Gerais State, where he was born, Jura attended the Federal University of Viçosa in his home state. Upon completing his Master’s degree at the university in 1995, he proceeded to USA’s Cornell University in 1998 for his PhD, under the watchful eye of Leon Kochian, another GCP Principal Investigator.

Sorghum rainbow_A Borrell

No, it’s not photo-shopped. This Australian sorghum-and-double-rainbows shot is from Supa Snappa, Andy Borrell, also a GCP sorghum Principal Investigator. See http://bit.ly/1tBAOMW

At Cornell, Jura worked with Leon on identifying the genes associated with aluminium tolerance in sorghum. “At the time, genes associated with aluminium tolerance were known for cereals in the Triticeae family (wheat, barley and rye). But the same genes were not found in the Poaceae family (sorghum, rice and maize). This suggested that there were different aluminium-tolerance genes at play, so it was a really pioneering project.” Continuing with the Cornell team after his PhD, Jura worked with Leon to  map the location of a major aluminium-tolerance genetic ‘hotspot’ in sorghum, which the project team contracted to  AltSB  for short (aluminium-tolerance gene or locus in Sorghum bicolor). The mapping also marked the next chapter  of what was to be a long-term professional relationship for the pair.

Brazil beckons, joining GCP, leadership and enduring partnerships
But in between, Brazil broke in and beckoned her native son home. And so it was that in 2002, Jura packed his bags and accepted a position with EMBRAPA’s maize and sorghum research centre. And despite the geographical distance, it wasn’t long before he and Leon teamed up again. “When I left Cornell, Leon and I had finished mapping AltSB and we were keen to clone it so we could then develop aluminium-tolerant sorghum varieties more efficiently,” says Jura.

Two years after his return to Brazil,  Leon and Jura – in 2004 – submitted a joint proposal for a competitive grant for their first GCP project on aluminium tolerance in cereals, premised on AltSB. This project contributed to GCP’s foundation work on sorghum in this and other projects, the common goal being a bid to provide farmers in the developing world with sorghum crops that would be able to tolerate harsh soils. But the project contributed much more with a deep taproot in pre-history, as that which we today call ‘sorghum’, ‘maize’ and ‘rice’ were once one millions of ‘Jurassic’ years ago. More on that interesting side-story.

And since this first project, EMBRAPA and Cornell University have collaborated with several other research institutes around the world, particularly in Africa.

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, Jura and Sam Gudu (Moi University) examine crosses between Kenyan and Brazilian maize, at the Kenya Agricultural Research Institute (KARI), Kitale, in May 2010.

Jura leads several EMBRAPA and GCP collaborative projects across three continents (Africa, Asia and the Americas). The partnerships forged by and through these projects go well beyond project life and frame, and will therefore continue after GCP’s sunset. Jura is both team leader and team player. And a couple of GCP projects in which Jura is part of the project team will run on in 2015 (see page 10), after GCP’s closure in December 2014.

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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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Oct 142014
 
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Things fall apart… and come together

By Eloise Phipps

Cassava – the tough, gutsy daughter of a poignant confluence of cultures, and the benevolent mother of millions when times get tough – is bursting onto the science scene after years of neglect. For October 15th, the International Day of Rural Women, we crown her the Queen of Crops. Read on to see why …

His mother and sisters worked hard enough, but they grew women’s crops, like coco-yams, beans and cassava. Yam, the king of crops, was a man’s crop.”

So wrote Chinua Achebe in his great novel, Things Fall Apart, set among the Igbo people in southeast Nigeria. His words are a reminder that men’s and women’s experiences, needs, activities and ambitions in the agricultural sphere can often be different – and that women’s contributions are all too often undervalued.

Cassava feeds more than half a billion people in the in the developing world. After rice and maize, it is the third-largest source of carbohydrates for people in the tropics, where it is grown across Africa, Asia and Latin America. Yet tough, unassuming cassava is a bit of an underdog – just like the women who grow it. We are celebrating the International Day of Rural Women by taking a special look at cassava, what it means for women, and the extraordinary things that can happen when Things Come Together!

A bright spot in a sea of green: a farmer in her field of cassava, in the village of Tiniu, near Mwanza, northern Tanzania.

A bright spot in a sea of green: a farmer in her field of cassava, in the village of Tiniu, near Mwanza, northern Tanzania.

It thrives on poor soils where other plants struggle, and it survives droughts that leave other crops biting the dust. For many rural mothers, cassava is the crop that keeps their families alive…”

“We must sing for you, great cassava…”

Hefty chunks of cassava – full of energy and nutrients – on sale in Kampala, Uganda.

Hefty chunks of cassava – full of energy and nutrients – on sale in Kampala, Uganda.

Cassava’s story is one that is inextricably linked to centuries of pain and struggle. It was introduced to Africa in the 16th century by Portuguese traders who brought it from Brazil – and took Africans back to Brazil as slaves.

Yam, native to Africa, was firmly established as the staple food of the Igbo people. Dominating their farming activities, it thus dominated the very routine of existence. So, control of yam affirmed men’s position at the top of the pinnacle. When cassava arrived, no one thought very much of it. For the Portuguese, it was a cheap source of carbohydrates. For the Igbo, it was a decidedly inferior crop to the long-beloved and much-revered yam.

Since the men were generally not much interested, Igbo women gradually adopted cassava as ‘their’ crop, a process that has been reinforced over the centuries. For example, Nigerian troop conscription during the First World War and the subsequent influenza pandemic caused a serious shortage of labour, particularly manpower. Women needed to grow more food, and cassava – more flexible and less labour-intensive than yam – was the natural choice, being also free from the cultural constraints that made yam the exclusive domain of men.

While no one would call cassava glamorous, plenty of women over the years have turned out to be quite happy that such a valuable crop ended up in their sphere of influence. While cassava is not often much of a cash crop in Africa, it is tough, resilient, and very useful for survival in difficult times. It thrives on poor soils where other plants struggle, and it survives droughts that leave other crops biting the dust. For many rural mothers, cassava is the crop that keeps their families alive.

The hard-working hands of Angelique Ipanga, a teacher and farmer, as she tends her cassava crop in Lukolela, Democratic Republic of Congo.

The hard-working hands of Angelique Ipanga, a teacher and farmer, as she tends her cassava crop in Lukolela, Democratic Republic of Congo.

What better words to sing cassava’s praises than those of Flora Nwapa, Nigeria’s first female novelist, in her Cassava Song? In ancient Igbo tradition, women sing their work, singing it into being and into completion, and her poem is a tribute to those work-songs.

And here, we have another Nigerian to join the chorus of praise – watch Emmanuel Okogbenin, molecular plant breeder, on the importance of cassava:

While our spotlight on Nigeria thus far has been purely coincidental, let’s also not forget that Nigeria is the global cassava giant, being far and away the world’s biggest producer and consumer of cassava. But do buckle up and let’s cross the great ocean, to another part of the planet, for an equally captivating cassava story…

 … legend has it that the first cassava was birthed by a human woman…”

Crossing continents: A virgin-born, Amazonian Snow White planted in the earth

Of course, cassava is not exclusively a female province – it is grown by both women and men farmers around the world. But can you blame us for imparting it with a special feminine mystique, when legend has it that the first cassava was birthed by a human woman caught at the confluence of two cultures?

Many centuries before the Europeans arrived, cassava – often known in the New World as manioc – sustained peoples and cultures throughout the tropical lowlands of the Americas. The Tupí people of Brazil tell how, many years ago, the daughter of a chief became pregnant. Although she said that she had not been with a man, her father did not believe her, and threatened to kill her if she did not tell him the name of the child’s father. When he slept, however, he dreamt of a white-skinned warrior who told him that his daughter was telling the truth, and that one day, she would bear a great gift for all his tribe.

The chief’s daughter gave birth to a little girl, Maní, whose skin was as white as the moon and eyes were as dark as the night. She grew into a happy and beautiful baby, but died suddenly after her first birthday. Her mother watered the grave every day, as was the custom, and one day, a strange plant grew there that no one had ever seen before. Later, the earth cracked open, and the Tupí people saw a fruit that was as white as the dead child. They drew it from the ground, peeled and cooked it, and to their surprise found that it was delicious, and even renewed their strength. They called it mandioca or manioca, meaning ‘House of Maní’.

It is a haunting tale, rich with echoes of the cultural upheavals that followed the coming of the Europeans, ancient fears of female impurity, and the realities of infant mortality. But it leaves one thing in no doubt: poor little Maní’s legacy was a precious treasure, not just for the Tupí but for the world.

Under the hot sun, the work goes on: a farmer tends her cassava crop in Colombia's southwestern Cauca department.

Under the hot sun, the work goes on: a farmer tends her cassava crop in Colombia’s southwestern Cauca department.

Proud in pink and polka dots: a farmer shows off a healthy cassava leaf in a plantation in Kampong Cham, Cambodia.

Proud in pink and polka dots: a farmer shows off a healthy cassava leaf in a plantation in Kampong Cham, Cambodia.

A busy Bea grows her way to cassava glory – with a little help from her friends

Female farmer reloaded: Being a rural woman farmer does not mean you have to have dirt under your fingernails all the time. Here’s Bea looking as elegant and regal as any queen.

Female farmer reloaded: Being a rural woman farmer does not mean you have to have dirt under your fingernails all the time. Here’s Bea looking as elegant and regal as any queen.

Ghanaian cassava researcher Elizabeth Parkes is no puny pushover, but even so she met her match in gutsy and determined farmer Bea. Elizabeth laughs as she remembers how the story began: “She hadn’t planted cassava before in her life, but she wanted to go into cassava production. She came to me – she pestered me actually! I was tired of it, because she didn’t know anything and it was a time when I was finishing my PhD, and I thought no, this lady cannot take this precious time from me.”

When most people think of a farmer, they probably think of a man in a straw hat. But in defiance of this stereotype, women make up 43 percent of the agricultural labour force in developing countries, rising to at least 50 percent in sub-Saharan Africa and Eastern Asia. These millions of rural women have incredibly diverse lives, but a few things stay surprisingly constant. Female farmers tend to produce less than their male counterparts – not because they are worse at farming, but because they have less access to all kinds of resources and opportunities. These include anything from land itself to improved seed and new technologies, and from education and information to financial credit.

If this gap could be completely sealed, women could increase their harvests by 20 to 30 percent, translating to millions fewer hungry and malnourished people worldwide. Fortunately, with the right kind of support, female farmers can – and do – transform their lives in remarkable ways. Bea’s story came to just such a happy ending: with guidance from Elizabeth, her cassava-growing skills took off like a rocket, and she became so successful that she was recognised as the best farmer in her community. “These are things that make me glad… that at least I have impacted somebody who hadn’t planted cassava before, and it’s amazing,” says Elizabeth. “There are people out there who need us, and when we give them our best, they will give the world their best as well.”

Listen to Elizabeth in the podcast below, and you are bound to pick up her infectious enthusiasm!

When scientists like these come together, with a dash of the right support, marvellous things happen… cassava has been given a voice.”

Things Come Together

Elizabeth Parkes is a woman from Ghana, and Chiedozie Egesi is a man from Nigeria, himself of the Igbo people and a yam breeder in a past life. However, the two have a lot in common. They are dynamic African scientists with a passion for social justice, and for helping the poorest and most disadvantaged rural people through their work on cassava. When scientists like these come together, with a dash of the right support, marvellous things happen.

Read Elizabeth’s story here and more from her here, and catch up with Chiedozie here and here.

Cassava has traditionally been a forgotten ‘orphan’ in crop science research. Humble and unfashionable, it also has some special challenges for breeders, like its long growth cycle and complicated genetics, while its tough and uncomplaining nature meant that many people thought of it as an “anywhere, anyhow” crop – a very misleading myth, if ever there was one (with thanks to myth-buster Joseph Adjebeng, for that memorable cassava quote). Although the idea grew from a kernel of truth, cassava, like any other crop, needs a little love, and yields less when plagued by problems such as diseases or degraded and infertile soils. But, like Harry Potter, in recent years this orphan has come out from the cupboard under the stairs, and the magic has begun.

Wreathed in sunlight and smiles, a cassava farmer inspects her crop in Kratie, Cambodia.

Wreathed in sunlight and smiles, a cassava farmer inspects her crop in Kratie, Cambodia.

Cassava’s no waif – luckily, as its tuberous roots are packed with staple carbohydrates. Here Ghanaian researcher Elizabeth Parkes shows off some huge and healthy cassava.

Cassava’s no waif – luckily, as its tuberous roots are packed with staple carbohydrates. Here Ghanaian researcher, Elizabeth Parkes, shows off some huge and healthy cassava. These days Elizabeth is a pro when it comes to things crop-related, but it was not always so. “I remember we used to uproot volunteer cocoyam from a serious, busy lady farmer’s farm and we put it in our garden expecting to have a fast-growing plant overnight,” she admits. “The crops died and the busy woman farmer had to come and warn us never to step in her farm again. That was the first hard lesson learnt.” Elizabeth remains ready to learn, with a healthy respect for the knowledge and skills of the farmers she works with, an attitude she learned early on when she visited cocoa farms near her home town. “I loved the way farmers called colleagues by making unique sounds,” she says. “There are many paths to the farm but everyone knew the many routes to our many farms. This still amazes me.”

The plus side of cassava being neglected for so long is that it only needed a relatively small initial investment in local capacity-building and applying modern breeding methods to make a big impact, and set the ball rolling for serious cassava research. “GCP helped us to build an image for ourselves in Nigeria and in Africa, and this created a confidence in other global actors, who, on seeing our ability to deliver results, are choosing to invest in us,” explains Chiedozie.

His team have released new cassava varieties that are resistant to diseases and rich in pro-vitamin A, providing the vitamin A that is particularly important for small children and childbearing women. He believes that these have the potential to transform the lives of the people – mainly rural women – who grow them. “The food people grow should be nutritious, resistant and high-yielding enough to allow them sell some of it and make money for other things in life, such as building a house, getting a motorbike, or sending their kids to school,” he says.

Elizabeth agrees that a new, “blessed and privileged era” has begun for cassava. “Thanks to funders such as GCP, who recognised that we couldn’t afford to turn a blind eye to the plight of this struggling crop, cassava has been given a voice.”

It seems that things have come together for cassava at last, and for Elizabeth, the personal rewards of being able to make real impacts are great. “I see African communities where poverty and hunger are seemingly huge problems with no way out; I’m fortunate to be working on a crop whereby, if I put in enough effort, I can bring some solutions.”

After all, it seems that being a ‘woman’s crop’ might not be a put-down, but something to celebrate. Cassava has come a long way, from a pale princess lying under the earth, to a steadfast mother keeping the family going in the toughest of times, to a confident and majestic queen with a glorious reign ahead of her.

And so, for October 15th, in honour of the International Day of Rural Women, we crown her the Queen of Crops. Long live Queen Cassava!

Colourful streamers for the coronation? No, they’re cassava noodles being made in Kampong Cham, Cambodia.

Colourful streamers for the coronation? No, they’re cassava noodles being made in Kampong Cham, Cambodia.

A regal African beauty tends her gorgeous cassava plants.

A regal African beauty tends her gorgeous cassava plants.

Links:  Our cassava Research | Slides | Podcasts Videos | InfoCentre | resaerch products

Jul 242014
 
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Read how this cocktail blends in a comparative genomics crucible, where both family genes and crop genes come into play in Brazil. Nothing whatsoever to do with the World Cup. It’s all about a passionate love affair with plant science – specifically a quest for aluminium-resilient maize – spanning a decade-and-a-half, and still counting…

Claudia

Claudia Guimarães

 

“I love the whole process of science; from identifying a problem, developing a method, conducting the experiments, analysing the data and evaluating the findings.” – Claudia Guimarães (pictured), Researcher at EMBRAPA Milho e Sorgo, Sete Lagoas, Brazil

I always enjoyed looking after the cattle and horses as well as planting and harvesting different crops.”

Forged on family farm, federal institute and foreign land
Claudia Guimarães is a plant molecular geneticist, with a pronounced passion for science. At the Federal University of Viçosa, Claudia studied agronomy because it provided a wide range of possibilities career-wise. She also believes her family’s farming background too had a part to play in her study and career choice. “My father has a farm in a small village 200 km north of Sete Lagoas. My whole family used to go there during our school holidays. I always enjoyed looking after the cattle and horses as well as planting and harvesting different crops.”

During her bachelor’s degrees, Claudia was increasingly drawn to plant genetics. She decided to pursue this field further and completed a Master’s degree in Genetics and Breeding, focusing on maize. She then completed a PhD in Comparative Genomics where she split her time between California and Brazil. “For my PhD, I got a scholarship from the Brazilian Council for Scientific and Technological Development which included international training in San Diego, California. During my PhD, I focused on comparative genomics for sugarcane, maize and sorghum, which involved genetic mapping and markers,” Claudia reveals.

Returning to Brazil after two years in California, Claudia joined the Brazilian Agricultural Research Corporation, commonly referred to as EMBRAPA (Empresa Brasileira de Pesquisa Agropecuária), where she has worked for the last 15 years, since 1999.

bCIMMYTmaizeField_w

Preparing to put her shoulder to the wheel, literally? Claudia in a maize field at the International Maize and Wheat Improvement Center (CIMMYT), Tlaltizapan, Mexico, in January 2010.

dNutrientSolutionEmbrapa_w

Maize plantlets cultivated in nutrient solution, the methodology Claudia and her team use to evaluate aluminium tolerance.

Our next challenge is to develop specific markers for a wider marker-assisted selection of aluminium tolerance in maize.”

Long-term allies in aluminium tolerance
EMBRAPA first became involved with GCP through one of its foundation programmes headed by Leon Kochian and his former PhD student Jurandir Magalhães. “Jura has been a really close friend for a long time,” explains Claudia. “We went to university together and have ended up working together here at EMBRAPA. I was involved in Jura’s project, which sought to clone a sorghum aluminium-tolerance gene.”

This gene is called SbMATE. Claudia continues, “EMBRAPA had a long-term aluminium-tolerance programme on maize and sorghum, within which there was a QTL mapping project for aluminium tolerance in maize, in which we started to look for a similar gene as the sorghum team.”

[Editor’s note: QTL stands for quantitative trait locus or loci – gene loci where allelic variation is associated with variation in a quantitative trait. An allele is a variant (different version) of a gene, that leads to variation in a trait, eg different colour for hair and eyes in human beings.]

Working with Leon Kochian at Cornell University, USA, Claudia and her team were able to find an important aluminium-tolerance gene homologue (loosely meaning a relative or counterpart) to the sorghum SbMATE, which they named ZmMATE. This gene is responsible for a major aluminium tolerance QTL that improves yield in acidic soil in maize breeding lines and hybrids. (see why scientists work jointly on closely related cereals)

“Identifying and then validating ZmMATE as the primary aluminium tolerance QTL in maize was a great project,” says Claudia. “Our next challenge is to develop specific markers for a wider marker-assisted selection of aluminium tolerance in maize.”

1: Rhyzobox containing two layers of Cerrado soil – a corrected top-soil and lower soils with 15 percent of aluminium saturation. We can see that near-isogenic lines (NILs) introgressed with the Al tolerance QTL (qALT6) that encompasses ZmMATE1 show deeper roots and longer secondary roots in acid soils, whereas the roots of L53 are mainly confined in the corrected top soil.  2: Maize ears, representing the improved yield stability in acid soils of a NIL per se and crossed with L3. NILs have the genetic background of L53 introgressed with qALT6, the major aluminium-tolerance QTL.

March 2014. Photo 1: Rhyzobox containing two layers of Cerrado soil – a corrected top-soil and lower soils with 15 percent aluminium saturation. We can see that near-isogenic lines (NILs) introgressed with the aluminium-tolerance QTL (qALT6) that encompasses ZmMATE1 show deeper roots and longer secondary roots in acidic soils, whereas the roots of L53 are mainly confined in the corrected top soil. Photo 2: Maize ears, representing the improved yield stability in acidic soils of a NIL per se and crossed with L3. NILs have the genetic background of L53 introgressed with qALT6, the major aluminium-tolerance QTL.

 

 …the students have really become my arms…  helping me a lot with the experiments…

Giving and receiving: students step in, partners in print
Supervising students has become a larger part of Claudia’s life since becoming a member of the Genetics Graduate Programme at Universidade Federal de Minas Gerais, in 2004. Because of this, she credits the students for helping her with her research. “I don’t have as much time as I used to in the lab, so the students have really become my arms in that area, helping me a lot with the experiments,” Claudia reveals. “This isn’t to say that they don’t have to think about what they are doing. I encourage them to always be thinking about why they are doing an experiment and what the result means. At the end of the day, they need to know more about what they are doing than I do, so they can identify indiscretions and successes.”

Claudia says she is always preaching three simple instructions to her students – work hard, always continue to learn and like what you do. “The last instruction is particularly important because as a scientist you need to dedicate a lot of time to what you do, so it helps if you like it. If you don’t like it then it becomes frustrating and no fun at all. I don’t think of my work as a job, rather as a passion. I just enjoy it so much!”

Claudia’s passion is not just a matter of the heart but also of the head, expressing itself in print. Her latest publication reflects the most current results on maize aluminium tolerance, highlighting GCP support, partnerships within and beyond EMBRAPA embracing Cornell University and the Agricultural Research Services of the United States Department of Agriculture (USDA–ARS) , as well as the strong presence of students. Check it out

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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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