Jan 122015
 
James profile

James Gethi and one of the crops closest to his heart – maize. He also has a soft spot for hardy crop varieties that survive harsh and unforgiving drylands, such as Machakos, Kenya, where this June 2011 photo of him with drought-tolerant KARI maize was taken.

As we tell our closing stories on our Sunset Blog, in parallel, we’re also catching up on the backlog of stories still in our store from the time GCP was a going concern. Our next stop is Kenya, and the narrative below is from 2012, but don’t go away as it is an evergreen – a tale that can be told at any time, as it remains fresh as ever. At that time, and for the duration of the partnership with GCP, the Food Crops Research Institute of the Kenya Agricultural and Livestock Research Organisation (KALRO) was then known as the Kenya Agricultural Research Institute (KARI), and we shall therefore stay with this previous name in the story. KARI was also the the name of the Kenyan institute at the time when James Gethi (pictured) left for a sabbatical at the International Maize and Wheat Improvement Center (CIMMYT by its Spanish acronym). On to the story then, and please remember we’re travelling back in time to the year 2012. 

“I got into science by chance, for the fun of it,” muses James, maize breeder and former GCP scientist “With agricultural school promising a flight to overfly the country’s agricultural areas– this was an interesting prospect for a village guy. ‘This could be fun’, I thought!”

And it turned out to be a chance well worth taking.  His first step was getting the requisite education. And so he armed himself with a BSc in Agriculture from the University of Nairobi, Kenya, topped with a Master’s and PhD in Plant Breeding from the University of Alberta (Canada) and Cornell University (USA), respectively. Beyond academics, in the course of his crop science career, James has developed 13 crop varieties, that included maize and cassava, published papers in numerous peer-reviewed papers (including the 2003 prize for Best paper in the field of crop science in the prestigious Crop Science journal. And in leadership, James headed the national maize research programme in his native Kenya. These are just a few of the achievements James has garnered in the course of his career, traversing  and transcending not only the geographical frontiers initially in his sights, but also scientific ones, reaching professional heights that perhaps his younger self might never have dreamt possible.

As a Research Officer at KARI, a typical day sees James juggling his time between hands-on research (developing maize varieties resistant to drought, field and storage pests) and project administration, coordinating public–private partnerships and the maize research programme at both institutional and country level. What motivates the man shouldering much of the responsibility for the buoyancy of his nation’s staple crop? James explains, “Making a difference by providing solutions to farmers. That’s my passion and that’s what makes me get up in the morning and go to work. It’s hugely satisfying!”

Without GCP, I would not be where I am today as a scientist… [it] gave me a chance to work with the best of the best worldwide… You develop bonds and understanding that last well beyond the life of the projects.”

Rapid transitions: trainee to trainer to leader
It was this passion and unequivocal dedication to his vocation – not to mention a healthy dollop of talent – that GCP was quick to recognise back in 2004, when James first climbed aboard the GCP ship. Like a duck to water, he proceeded to engage in all manner of GCP projects and related activities, steadily climbing the ranks from project collaborator to co-Principal Investigator and, finally, Principal Investigator in his own right, leading a maize drought phenotyping project. Along the way, he also secured GCP Capacity building à la carte and Genotyping Support Service grants to further the maize research he and his team were conducting.

Combo1

FLASHBACK: At a GCP drought phenotyping course in mid-2006 at Montpellier, France. (1) James (left) pays keen attention during one of the practical sessions. (2) In the spirit of “All work and no play, etc”, taking a break from the course to take in some of the sights with colleagues. Clearly, James, “the guy from the village” is anything but a dull boy! Next to James, second left, is BM Prasanna, currently leader of CIMMYT’s maize programme.

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From trainee to trainer and knowledge-sharer: James (behind the camera) training KARI staff on drought phenotyping in June 2009 at Machakos, in Kenya’s drylands.

The GCP experience, James reveals, has been immensely rewarding: “Without GCP, I would not be where I am today as a scientist,” he asserts. And on the opportunity to work with a capable crew beyond national borders, as opposed to operating as a solo traveller, he says: “GCP gave me a chance to work with the best of the best worldwide, and has opened up new opportunities and avenues for collaboration between developing-country researchers and advanced research institutes, creating and cementing links that were not so concrete before. This has shown that we don’t have to compete with one another; we can work together as partners to derive mutual benefits, finding solutions to problems much faster than we would have done working alone and apart from each other.”

The links James has in mind are not only tangible but also sustainable: “You develop bonds and understanding that last well beyond the life of the projects,” James enthuses, citing additional professional engagements (the African Centre for Crop Improvement in KwaZulu-Natal, South Africa, and the West Africa Centre for Crop Improvement, have both welcomed James and his team into their fold), as well as firm friendships with former GCP project colleagues as two key take-home benefits of his interaction with the Programme. These new personal and professional circles have fostered a happy home for dynamic debates on the latest news and views from the crop-science world, and the resultant healthy cross-fertilisation of ideas, James affirms.

Reflecting on what he describes as a ‘mentor’ role of GCP, and on the vital importance of capacity building in general, he continues: “By enhancing the ability of a scientist to collect germplasm, or to analyse that germplasm, or by providing training and tips on how to write a winning project proposal to get that far in the first place, you’re empowering scientists to make decisions on their own – decisions which make a difference in the lives of farmers. This is tremendous empowerment.”

Another potent tool, says James, is the software made available to him through GCP’s Integrated Breeding Platform (IBP), which is a handy resource package to dip into for – among other things – analysing data and selecting the right varieties at the right time. The next step for IBP, he feels, should be scaling up and aiming for outreach to the wider scientific community, forecasting that such a step could bring nothing but success: “The impacts could be enormous!” he projects, with a palpable and infectious enthusiasm.

People… don’t eat publications, they eat food… I’m not belittling knowledge, but we can do both”

Fast but not loose on the R&D continuum: double agent about?
For James, outreach and impacts are not limited to science alone. In parallel with his activities in upstream genetic science, James’ efforts are equally devoted to the needs of his other client base-–the development community and farmers. For this group, James’ focus is on putting tangible products on the table that will translate into higher crop yields and incomes for farmers. Yet whilst products from any highly complex scientific research project worth its salt are typically late bloomers, often years in the making on a slow burner as demanded by the classic linear R&D view that research must always precede development, adaptation and final adoption, James has been quick to recognise that actors in the world of development and the vulnerable communities they serve do not necessarily have this luxury of time.

 August 2008: a huge handful, and more where that came from in Kwale, Kenya. This farmer's healthy harvest came from KARI hybrids.

August 2008: a huge handful, and more where that came from in Kwale, Kenya. This farmer’s healthy harvest came from KARI hybrids.

His solution for this challenge? “Sitting where I sit, I realised from very early on that if I followed the traditional linear scientific approach, my development clients would not take it kindly if I still had no products for them within the three-year lifespan of the project. The challenge then was to deliver results for farmers without compromising or jeopardising their integrity or the science behind the product,” he recalls. In the project he refers to – a GCP-funded project to combat drought and disease in maize and rice – James applied a novel double-pronged approach to get around this seeming conundrum of the need for sound science on the one hand, and the need for rapid results for development on the other hand. Essentially, he simultaneously walked on both tracks of the research–development continuum.

The project – led by Rebecca Nelson of Cornell University and with collaborators including James’ team at KARI (leading the maize component), the International Rice Research Institute (IRRI), researchers in Asia, as well as other universities in USA – initially set out with the long-term goal of dissecting quantitative trait loci (QTLs) for rice and maize with a view to combating drought and disease in these crops. Once QTLs were dissected and gene crosses done, James and his team went about backcrossing these new lines to local parental lines, generating useful products in the short term. The results, particularly given the limited resources and time invested, have been impressive, with seven hybrid varieties developed for drylands and coastal regions having been released in Kenya by 2009, and commercialised from 2010.

James and his colleagues have applied the same innovative approach to other GCP projects, grappling to get a good grasp of the genetic basis of drought tolerance, whilst also generating intermediate products for practical use by farmers along the way. James believes this dual approach paves the way for a win-win situation: “People on the ground don’t eat publications, they eat food,” he says. “As we speak now, there are people out there who don’t know where their next meal will come from. I’m not belittling knowledge, but we can do both – boiled maize on the cob and publications on the boil. But let’s not stop at crop science  and knowledge dissemination – let’s move it to the next level, which means products,” he challenges, adding: “With GCP support, we were able do this, and reach our intended beneficiaries.”

It is perhaps this kind of vision and inherent instinct to play the long game that has taken James this far professionally, and that will no doubt also serve him well in the future.

As our conversation comes to a close, we ask James for a few pearls of wisdom for other young budding crop researchers eager to carve out an equally successful career path for themselves, James offers “Form positive links and collaborations with colleagues and peers. Never give up; never let challenges discourage you. Look for organisations where you can explore the limits of your imagination. Stay focused and aim high, and you’ll reach your goal.”

Upon completion of his ongoing sabbatical at CIMMYT in Zimbabwe, where he is currently working on seed systems, James plans to return to KARI, armed with fresh knowledge and ready to seize – with both hands – any promising collaborative opportunities that may come his way .

Certainly, prospects look plentiful for this ‘village lad’ in full flight, and who doesn’t look set to land any time soon!

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In full flight – Montpellier, Brazil, Benoni, Bangkok, Bamako, Hyderabad… our boy voyaged from the village to Brazil and back, and far beyond that. Sporting the t-shirt from GCP’s Annual Research Meeting in Brazil in 2006, which James attended, he also attended the same meeting the following year, in Benoni, South Africa, in 2007, when this photo was taken. James is a regular at these meetings which are the pinnacle on  GCP’s calendar (http://bit.ly/I9VfP4). But he always sings for his supper and is practically part of the ‘kitchen crew’, but just as comfortable in high company. For example, he was one of the keynote speakers at the 2011 General Research Meeting (see below).

Links:

 

 

Aug 292014
 
One of the greatest challenges of our time is growing more crops to feed more people, but using less water

Sorghum is one of the most ‘efficient’ crops in terms of needing less water and nutrients to grow. And although it is naturally well-adapted to sun-scorched drylands, there is still a need to improve its yield and broad adaptability in these harsh environments. In West Africa, for example, while sorghum production has doubled in the last 20 years, its yield has remained stagnant – and low.

The GCP Sorghum Research Initiative comprises several projects, which are exploring ways to use molecular-breeding techniques to improve sorghum yields, particularly in drylands. All projects are interdisciplinary international collaborations with an original focus on Mali, where sorghum-growing areas are large and rainfall is getting more erratic and variable. Through the stay-green project, the research has since broadened to also cover Burkina Faso, Ethiopia, Kenya, Niger and Sudan.

Using molecular markers is new and exciting for us as it will speed up the breeding process. With molecular markers, you can easily see if the plant you’ve bred has the desired characteristics without having to grow the plant and or risk missing the trait through visual inspection.”

What’s MARS got to do with it?

Niaba Témé is a local plant breeder and researcher at Mali’s L’Institut d’économie rurale (IER). He grew up in a farming community on the southern edge of the Sahara Desert, where crops would constantly fail during drier-than-normal seasons.

Niaba Teme

Niaba Témé

Niaba says these crop failures were in part his inspiration for a career where he could help farmers like his parents and siblings protect themselves from the risks of drought and extreme temperatures.

For the past four years, Niaba and his team at IER have been collaborating with Jean-François Rami and his team at France’s Centre de coopération internationale en recherche agronomique pour le développement (CIRAD), to improve sorghum grain yield and quality for West African farmers. The work is funded by the Syngenta Foundation for Sustainable Agriculture.

“With the help of CIRAD and Syngenta, we have been learning how to use molecular markers to improve breeding efficiency of sorghum varieties more adapted to the variable environment of Mali and surrounding areas which receive less than 600 millimetres of rainfall per year,” he says.

Jean-François Rami

Jean-François Rami

“Using molecular markers is new and exciting for us as it will speed up the breeding process. With molecular markers, you can easily see if the plant you’ve bred has the desired characteristics without having to grow the plant and or risk missing the trait through visual inspection.”

Jean-François Rami, who is the project’s Principal Investigator, has been impressed by the progress made so far. Jean-François is also GCP’s Product Delivery Coordinator for sorghum.

“Since its inception, the project has progressed very well,” says Jean-François. “With the help of the IER team, we’ve been able to develop two bi-parental populations from elite local varieties, targeting two different environments of sorghum cropping areas in Mali. We’ve then been able to use molecular markers through a process called marker-assisted recurrent selection [MARS] to identify and monitor key regions of the genome in consecutive breeding generations.”

The collaboration with Syngenta came from a common perspective and understanding of what approach could be effectively deployed to rapidly deliver varieties with the desired characteristics.

“Syngenta came with their long experience in implementing MARS in maize. They advised on how to execute the programme and avoid critical pitfalls. They offered to us the software they have developed for the analysis of data which allowed the project team to start the programme immediately,” says Jean-François.

Like all GCP projects, capacity building is a large part of the MARS project. Jean-François says GCP has invested a lot to strengthen IER’s infrastructure and train field technicians, researchers and young scientists. But GCP is not the only player in this: “CIRAD has had a long collaboration in sorghum research in Mali and training young scientists has always been part of our mission. We’ve hosted several IER students here in France and we are interacting with our colleagues in Mali either over the phone or travelling to Mali to give technical workshops in molecular breeding. The Integrated Breeding Platform [IBP] has also been a breakthrough for the project, providing to the project team breeding services, data management tools, and a training programme – the Integrated Breeding Multiyear Course [IB–MYC].”

We don’t have these types of molecular-breeding resources available in Mali, so it’s really exciting to be a part of this project… the approach has the potential to halve the time it takes to develop local sorghum varieties with improved yield and adaptability to drought… one of the great successes of the project has been to bring together sorghum research groups in Mali in a common effort to develop new genetic resources for sorghum breeding.”

Back-to-back: more for Mali’s national breeding programme

On the back of the MARS project, Niaba successfully obtained GCP funding in 2010 to carry out similar research with CIRAD and collaborators in Africa at the International Crops Research Institute for the Semi-Arid Tropics (ICRISAT).

“In this project, we are trying to enhance sorghum grain yield and quality for the Sudano-Sahelian zone of West Africa using the backcross nested association mapping (BCNAM) approach,” explains Niaba, who is the Principal Investigator of the BCNAM project. “This involves using an elite recurrent parent that is already adapted to local drought conditions. The benefit of this approach is that it can lead to detecting elite varieties much faster.”

Kirsten Vom Brocke (CIRAD) Michel Vaksmann (CIRAD) Mamoutou Kouressy (IER) Eva Weltzien (ICRISAT) Jean-Francois Rami (CIRAD) Denis Lespinasse (Syngenta) Niaba Teme (IER) Ndeye Ndack Diop (GCP) Ibrahima Sissoko (Icrisat) Fred Rattunde (Icrisat)

A ‘sample’ of the rich mix of international partners in sorghum research: Left to right – Kirsten Vom Brocke (CIRAD), Michel Vaksmann (CIRAD), Mamoutou Kouressy (IER), Eva Weltzien (ICRISAT), Jean-François Rami (CIRAD), Denis Lespinasse (Syngenta), Niaba Teme (IER), Ndeye Ndack Diop (GCP Capacity Building Leader), Ibrahima Sissoko and Fred Rattunde (both from ICRISAT).

Eva Weltzien has been the Principal Scientist for ICRISAT’s sorghum breeding programme in Mali since 1998. She says the project aligned with much of the work her team had been doing, so it made sense to collaborate considering the new range of sorghum genetic diversity that this approach aims to use.

“We’ve been working with Niaba’s team to develop 100 lines for 50 populations from backcrosses carried out with 30 recurrent parents,” explains Eva. “These lines are being genotyped by CIRAD. We will then be able to use molecular markers to determine if any of these lines have the traits we want. We don’t have these types of molecular-breeding resources available in Mali, so it’s really exciting to be a part of this project.”

Eva Weltzien (holding sheet of paper) presenting to Mali's Minister of Agriculture (in white cap) a graph on the superiority of new guinea race hybrids. Also on display are panicles and seed of the huybrids and released varieties of sorghum in Mali. The occasion was an annual field day at ICRISAT's research station at Samanko, Mali.

An annual field day at ICRISAT’s research station at Samanko, Mali. Eva Weltzien (holding sheet of paper) showing Mali’s Minister of Agriculture, Tiemoko Sangare, (in white cap) a graph on the superiority of new guinea race hybrids. Also on display are panicles and seed of the hybrids and released varieties of sorghum in Mali.

Eva says that the approach has the potential to halve the time it takes to develop local sorghum varieties with improved yield and adaptability to drought.

For Jean-François, one of the great successes of the project has been to bring together sorghum research groups in Mali in a common effort to develop new genetic resources for sorghum breeding.

“This project has strengthened the IER and ICRISAT partnerships around a common resource. The large multiparent population that has been developed is analysed collectively to decipher the genetic control of important traits for sorghum breeding in Mali,” says Jean-François.

 Plants with this ‘stay-green’ trait keep their leaves and stems green during the grain-filling period. Typically, these plants have stronger stems, higher grain yield and larger grain.”

Sorghum staying green and strong, with less water

In February 2012, Niaba and his colleague, Sidi B Coulibaly, were invited to Australia as part of another Sorghum Research Initiative project they had been collaborating on with CIRAD, Australia’s University of Queensland and the Queensland Department of Agriculture, Fisheries and Forestry (QDAFF).

“We were invited to Australia for training by Andrew Borrell and David Jordan, who are co-Principal Investigators of the GCP stay-green sorghum project,” says Niaba.

Left to right: Niaba Teme (Mali), David Jordan (Australia), Sidi Coulibaly (Mali) and Andrew Borrell (Australia) visiting an experiment at Hermitage Research Facility in Queensland, Australia.

Left to right: Niaba Témé (Mali), David Jordan (Australia), Sidi Coulibaly (Mali) and Andrew Borrell (Australia) visiting an experiment at Hermitage Research Facility in Queensland, Australia.

“We learnt about association mapping, population genetics and diversity, molecular breeding, crop modelling using climate forecasts, and sorghum physiology, plus a lot more. It was intense but rewarding – more so the fact that we understood the mechanics of these new stay-green crops we were evaluating back in Mali.”

It wasn't all work and there was clearly also time to play, as we can see her., Sidi Coulibaly and Niaba Teme visiting with the Borrell family in Queensland, Australia.

It wasn’t all work and there was clearly also time to play, as we can see here., where Sidi Coulibaly and Niaba Témé are visiting the Borrell family in Queensland, Australia.

Stay-green is a post-flowering drought adaptation trait that has contributed significantly to sorghum yield stability in northeastern Australia and southern USA over the last two decades.

Andrew has been researching how the drought-resistant trait functions for almost 20 years, including gene discovery. In 2010, he and his colleague, David Jordan, successfully obtained funding from GCP to collaborate with IER and CIRAD to develop and evaluate drought-adapted stay-green sorghum germplasm for Africa and Australia.

“Stay-green sorghum grows a canopy that is about 10 per cent smaller than other lines. So it uses less water before flowering,” explains Andrew. “More water is then available during the grain-filling period. Plants with this ‘stay-green’ trait keep their leaves and stems green during the grain-filling period. Typically, these plants have stronger stems, higher grain yield and larger grain.”

Andrew says the project is not about introducing stay-green into African germplasm, but rather, enriching the pre-breeding material in Mali for this drought-adaptive trait.

The project has three objectives:

  1. To evaluate the stay-green drought-resistance mechanism in plant architecture and genetic backgrounds appropriate to Mali.
  2. To develop sorghum germplasm populations enriched for stay-green genes that also carry genes for adaptation to cropping environments in Mali.
  3. To improve the capacity of Malian researchers by carrying out training activities for African sorghum researchers in drought physiology and selection for drought adaptation in sorghum.

…we have found that the stay-green trait can improve yields by up to 30 percent in drought conditions with very little downside during a good year, so we are hoping that these new lines will display similar characteristics”

Expansion and extension:  beyond Mali to the world

Andrew explains that there are two phases to the stay-green project. The project team first focused on Mali. During this phase, the Australian team enriched Malian germplasm with stay-green, developing introgression lines, recombinant inbred lines and hybrids. Some of this material was field-tested by Sidi and his team in Mali.

“In the past, we have found that the stay-green trait can improve yields by up to 30 percent in drought conditions with very little downside during a good year, so we are hoping that these new lines will display similar characteristics,” says Andrew. “During the second phase we are also collaborating with ICRISAT in India and now expanding to five other African countries – Niger and Burkina Faso in West Africa; and Kenya, Sudan and Ethiopia in East Africa. During 2013, we grew our stay-green enriched germplasm at two sites in all these countries. We also hosted scientists from Burkina Faso, Sudan and Kenya to undertake training in Queensland in February 2014.”

 

A sampling of some of stay-green sorghum partnerships in Africa. (1)  Asfaw Adugna assessing the genetic diversity of  sorghum panicles produced from the GCP collaboration at Melkassa, Ethiopia. (2)  Clarisse Barro-Kondombo (Burkina Faso) and Andrew Borrell (Australia) visiting a lysimeter facility in Hyderabad, India, as part of GCP training. (3) Clement Kamau (Kenya, left) and  Andrew Borrell (Australia, right) visiting the seed store at the Kenya Agricultural Research Institute (KARI) in Katumani, Kenya.

A sampling of some of stay-green sorghum partnerships in Africa. (1) Asfaw Adugna of the Ethiopian Institute of Agricultural Research (EIAR)  assessing the genetic diversity of sorghum panicles produced from the GCP collaboration at Melkassa, Ethiopia. (2) Clarisse Barro-Kondombo (left, INERA – Institut de l’environnement et de recherches agricoles , Burkina Faso) and Andrew Borrell (right) visiting a lysimetre facility at ICRISAT’s headquarters in Hyderabad, India, as part of GCP training, in February 2013. (3) Clement Kamau (left, Kenya Agricultural Research Institute [KARI] ) and Andrew Borrell (right) visiting the seed store at KARI, Katumani, Kenya.

Andrew says that the collaboration with international researchers has given them a better understanding of how stay-green works in different genetic backgrounds and in different environments, and the applicability is broad. Using these trial data will help provide farmers with better information on growing sorghum, not just in Africa and Australia, but also all over the world.

“Both David and I consider it a privilege to work in this area with these international institutes. We love our science and we are really passionate to make a difference in the world with the science we are doing. GCP gives us the opportunity to expand on what we do in Australia and to have much more of a global impact.”

We’ll likely be hearing more from Andrew on the future of this work at GCP’s General Research Meeting (GRM) in October this year, so watch this space! Meantime, see slides below from GRM 2013 by the Sorghum Research Initiative team. We also invite you to visit the links below the slides for more information.

Links

Jul 042012
 

The GCP community, its labours and joys

If tools and resources are not put to use, then we labour in vain...GCP contributes to food security by providing breeders with integrated tools, techniques and services to speed up the selection cycle, be this by conventional or molecular breeding. GCP focuses on developing new materials and new techniques and delivering these, and the appropriate breeding tools, technologies and services, to breeders. I think GCP has been one of the most successful builders of research and development partnerships.

The Board’s focus is now on auditing the Programme, and mapping a strategy to sustain its successful partnerships and systems, so that these can continue to deliver products and capacity to the developing world.”

Seatbelts on please! Time to take a tour with Andrew, for an ‘aerial’ view of GCP from the very  ‘top’.

Please meet Andrew Bennett (pictured), the Chair of GCP’s Executive Board. Among other responsibilities, he is also President of the Tropical Agricultural Association, UK, chairs the SciDev.Net Board, and previously chaired the CIFOR Board. He was formerly Executive Director of the Syngenta Foundation and Director of Rural Livelihoods and Environment at the Department for International Development (DFID, UK) where he was responsible for professional advice on policy and programmes on livelihoods, natural resources, environment, sustainable development and research. Andrew has worked on development programmes in Africa, Asia, Latin America, the Pacific and the Caribbean.

Today, Andrew shares his perspectives on GCP’s work, its impact, the challenges, the community GCP has built, and the role of the Board. Please read on…

When was the GCP Board established, and what is its profile and role?
The Board was set up in mid-2008 towards the end of the first phase of the Programme. A review recommended that there be a fully independent Board, comprising people who had no conflict of interest with the Programme to facilitate decision-making.

Board members have between them a wide variety of skills and backgrounds, ranging from expertise in molecular biology to development assistance, socioeconomics, academia, finance, governance and change management.

We are committed to the role that can be played by science in development, and to the Programme. We have offered advice and helped the Programme’s Consortium Committee and management refocus the Programme. By all accounts, they seem happy with how things have evolved.

Because GCP is hosted by CIMMYT, the Board does not have to deal with any policy issues. That is the responsibility of the Consortium Committee. Our role is more to provide advice and to help with decision-making and implementation, which is great as we’ve been able to focus on the Programme’s science and people.

How long have you been involved with GCP?
Since the Board was established in 2008.

What does the GCP tagline – ‘Partnerships in modern crop breeding for food security’ – mean for you?
It means that all our undertakings are geared towards producing crop varieties that are tolerant to a range of environments, as well as being socially acceptable and appealing to farmers and markets.

How do you upgrade the planting material farmers have by fortifying it to combat the biotic and abiotic stresses? Half the challenge is breeding and selecting good material, and the other half is ensuring delivery of tools to breeders and new planting materials to farmers.

So GCP focuses on developing new materials and new techniques and delivering these, and the appropriate breeding tools, technologies and services, to breeders.

Why is GCP’s work important, and what does it mean for food security?
People who are food-secure have access to adequate food at all times to maintain healthy active lives. There are two sides to making this happen – access and availability.

GCP is increasing the number of varieties and lines tolerant to the conditions farmers are facing. What we cannot do is put money in the hands of poor people. If we supply people with the means to produce sustainable and healthy crops, they will have the means to produce food for themselves, and a means of making an income.

GCP contributes to food security by providing breeders with integrated tools, techniques and services to speed up the selection cycle, be this by conventional or molecular breeding.

For you, what have been the major outcomes of GCP so far?
GCP has shown that it is possible to form very productive partnerships across CGIAR institutes and advanced research establishments and those countries that have less scientific capacity. I think it has been one of the most successful builders of research and development partnerships. GCP has also shown public researchers can work very well with the private sector. The public sector has the means to build a lot of capacity.

I think GCP has demonstrated that it is possible to establish molecular breeding programmes in those parts of the world that do not have well-developed scientific infrastructure.

Just a little bit of money – relatively speaking of course – clear vision, and good leadership, can go very far, and produce tremendous benefits and progress.

GCP has also identified the constraints that we have to work within – the challenge of phenotyping and restrictions on the movement of genetic material to other parts of the world. GCP has paid particular attention to intellectual property [IP] because the information and materials GCP produces must remain in the public domain. IP in the international arena within which the Programme operates must span potentially conflicting national legislation regimes. It is a very complex area.

‘Challenge’ is in GCP’s name. What are the major challenges that the Programme has so far overcome?
Quite a number and more could be on the horizon. GCP has overcome some of these challenges. They include the problem of poor-quality phenotyping. This has been addressed through a comprehensive capacity-building programme, including laboratory and field infrastructure, and the training of research support staff in the developing-country field sites where GCP projects are being implemented.

Another challenge was focusing the Programme. At the start, the Programme was spread too thin, spanning too many crops and partners, but these have been progressively narrowed down in Phase II.

This narrowing is no mean feat in the public sector. In the private sector, you start with, say, a hundred projects, then after six months you halve them. After a year, you are down to 10 projects and you put all your resources into making those 10 ‘winners’ work. In the public sector, you keep the entire hundred going for three years, then you look for funding to keep them all running for another cycle. It’s a different culture: the private sector is product-oriented, while some aspects of the public sector emphasise contributing to the growth of knowledge and information, and to building or maintaining relationships, without necessarily asking about their usefulness and benefits to society.

The Board’s focus is now on auditing the Programme and mapping a strategy to sustain its successful partnerships and systems, so that these can continue to deliver products and capacity to the developing world.”

What are the future challenges that the Programme must overcome to remain sustainable?
There are many GCP activities that can be integrated into the new CGIAR Research Programmes. However, there may be other activities such as capacity building and IP management which – at this point in time – appear somewhat less easy to integrate into the new CGIAR Research Programmes.

There is also a danger – not unique to GCP but with all aid-assisted programmes – that when the money ends, everything will disappear into the archives. We have to make sure that doesn’t happen in this instance.

The Board’s focus is now on auditing the Programme and mapping a strategy to sustain its successful partnerships and systems, so that these can continue to deliver products and capacity to the developing world.

What are some of the lessons learnt so far?
GCP was born at a time when we thought molecular biology could solve all our problems quickly and efficiently. What I think we are finding is that molecular tools –while extremely useful – cannot entirely replace understanding the agronomy and phenotypic activities. Molecular biology alone is not a panacea or silver bullet for crop breeding; but it is a valuable tool.

Then there is capacity building: molecular breeding is a tool that you can only use if you have the capacity. Many parts of the world will require a lot of capacity building and support to be able to use the tools. GCP and its Integrated Breeding Platform can make a modest contribution to meeting this need through the proof-of-concept GCP Research Initiatives for selected crops and countries and establishing communities of practice.

If tools and resources are not put to use, then we labour in vain.

What has been the most enjoyable aspect of your position with GCP?
Without a doubt, attending the General Research Meetings has been the most enjoyable, meeting scientists from a wide range of institutes, backgrounds and countries.

These scientists come together because they share the same interests and a common goal. There’s a lively buzz of conversation. It is good to hear about what they are doing, what their aspirations are, and to learn from the knowledge and posters they bring to the meeting.

You don’t have to be a cutting-edge scientist to listen to these people whose enthusiasm is palpable. They are passionate, have a strong sense of community, enjoy what they are doing, and are just as keen to share this knowledge and enthusiasm. It’s all highly infectious!

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