Agricultural research uplifts lives

A yam trader happily showing off his ware. With appropriate agricultural infrastructure, input, and policy support, Africa can indeed feed itself. Photo by IITA.
A yam trader happily showing off his ware. With appropriate agricultural infrastructure, input, and policy support, Africa can indeed feed itself. Photo by IITA.

A study on the impact of agricultural research on productivity and poverty in sub-Saharan Africa (SSA) that we completed this year has shown that agricultural research has a direct positive impact on poverty, reducing the number of poor people in the region by as much as 2.3 million annually.

According to the study, in view of the long-term research investments and demonstrated successes in SSA, our own R4D work is helping uplift the lives of about 500,000 to one million poor people in the region per year.

The study, authored by Arega Alene, Impact Assessment Economist, and Ousmane Coulibaly, Agricultural Economist, also estimated that the aggregate rate of return to agricultural research in the region runs as high as 55 percent.

However, the study cautions that the actual impacts are not large enough to offset the poverty-increasing effects of population growth and environmental degradation in the region.

The study, which has been published in the journal Food Policy, further demonstrated that doubling investments in agricultural R&D in SSA from the current US$650 million annually could reduce poverty in the region by two percentage points per year. However, the study adds that this projected drop in poverty would not be realized unless existing extension, credit, and input supply systems become more efficient.

The study also established that agricultural research had contributed significantly to productivity growth in SSA, with the highest payoffs noted in Ghana, Cameroon, Nigeria and Ethiopia. This is attributed to sustained investments in building national research capacity, long-term operations of the Consultative Group on International Agricultural Research (CGIAR), North Face Jacket Sale UK and regional technology spillovers. Work by the CGIAR contributed about 56% of the total poverty reduction impact in the sub-region.

Despite the contributions of agricultural research, the study notes that SSA faces several unique constraints outside the research realm that hinder the realization of potential benefits. It singled out weak extension systems, lack of efficient credit and input supply systems, and poor infrastructure development. The study recommended that concerned entities undertake efforts to improveNorth Face Sale these systems and related infrastructure, and increase investments in agricultural research, to further reduce poverty in SSA.

Africa can feed itself

Gari for sale at a wholesale market in Ihugh, Benue state, Nigeria. Photo by IITA.
Gari for sale at a wholesale market in Ihugh, Benue state, Nigeria. Photo by IITA.

Even while nearly a quarter of the world’s one North Face UK Sale the more obvious stuff off billion-plus hungry are in Africa, the continent can easily meet its food and income needs with additional investments in agriculture, particularly in research and capacity-building. This was the general sentiment aired by agricultural experts gathered at a World Food Day 2009 forum that we organized in Lusaka, Zambia in October.

By investing in research and training, simple but effective technologies that already exist can be easily made available to African farmers to improve their productivity, which is currently very low compared to global average.

If the gap between potential and actual yields can be reduced using existing science, Africa’s production can increase three-fold. However, farmers must be able to generate wealth from the increased yields. This is not always the case as a lot of produce go to waste before and after harvesting.

In Africa, an increase in production usually results in a drop in prices, which consequently means lesser incomes for farmers. Produce must also be protected from pests and diseases and from losses during transportation and storage. Alternative markets are needed to prevent prices from spiraling down with increased production.

Other lessons floated during the forum included the need to develop mechanisms to help farmers cope with the lingering effects of the global financial and food crises, strengthening the agricultural research backbone of Africa, and creating an enabling environment for farmers.

Experts said research and training institutions must come together to produce a labor force that is knowledgeable and ready to face the challenges of climate change on agriculture, and quickly find and disseminate solutions. This becomes more apparent considering that over 60 percent of the continent’s population depends heavily on agriculture for their livelihoods, with 70 percent of this comprising subsistence agriculture. Most also depend on the rains, which makes agriculture even more uncertain because of climate change.

They were also in agreement that in order to increase agricultural productivity in Africa, farmers should also start increasing their farm inputs. To achieve this, farmers need a lot of motivation through an agriculture-friendly policy environment andportlandhallhotel water-Th i will tepid to rewarding support for improved access to feed, fertilizer, irrigation, and other inputs.

They supported the call for more investment in agricultural research and training to fight food insecurity and poverty in Africa. However, they emphasized that farmers need to actively participate in research to ensure that the technologies produced are appropriate and acceptable to them.

Developing dual-resistance cassava

Cassava root rot caused by CBSD. Photo by IITA.
Cassava root rot caused by CBSD. Photo by IITA.

This year, we moved closer to developing North Face Sale a few too mild properly and so forth!
cassava with dual resistance to Cassava Mosaic Disease (CMD) and Cassava Brown Streak Disease (CBSD) – the most devastating diseases of the crop in Eastern and Central Africa and the greatest threats to the food security and livelihoods of over 200 million people.

In Uganda, we selected eight clones with resistance to CMD and CBSD and other farmer-preferred traits. These clones, which are the first ones with dual resistance suitable to the mid-altitude areas of the Great Lakes regions, were sent to the Kenya Plant Health Inspectorate Services for cleaning and multiplication in preparation for regional distribution to national partners. An additional 41 yellow-fleshed clones, also with dual resistance to CMD and CBSD, are undergoing advanced evaluation.

This is the fourth year of trials for dual-resistance cassava for mid-altitudes in Uganda. The trials are being conducted in Mukono and Namulonge, considered hot spots of CBSD and CMD in the country. The breeding work started with over 5000 true seeds of parents with tolerance to CBSD from Tanzania that were sent to Uganda for crossing with IITA varieties that are resistant to CMD.

Cassava grown from the Tanzanian seeds were repeatedly subjected to high disease pressure along with susceptible varieties for comparison. From each growing season, only 10 percent of the crop was selected for the next stage. After four growing seasons, the field has been narrowed down to eight very promising varieties.

Similar dual-resistance evaluation was carried out in Tanzania. Eight clones that have resistance to both CMD andeducate North Face Jacket Sale yourself on the way th much CBSD were deliberately subjected to the diseases by grafting them with infected plants. Five of these clones are being evaluated on-farm, while 11 clones with dual resistance and high starch content – a preferred trait by farmers – are also being evaluated.

Cassava that survives these tests, thereby producing a true dual-resistant variety, can then be used for further disease-resistance breeding in other countries in the Great Lakes region such as Rwanda, Kenya, and DR Congo. Throughout the selection process, farmers were actively engaged to ensure that the varieties meet their preferences such as cooking taste, texture, and yield.

A novel way to propagate yams

A rooted yam vine cutting, which would soon be ready for transplanting in the field. Photo by O Adebayo, IITA.
A rooted yam vine cutting, which would soon be ready for transplanting in the field. Photo by O Adebayo, IITA.

In the traditional method of growing yam, appearance dryfarmers set aside 25 to 30 percent of the harvested tubers as seeds for the next planting season. This makes the crop expensive to produce. It is also inefficient: the multiplication rate is only about 1:5-10, which pales in comparison, for instance, to cereals that have a propagation ratio of about 1:300.

To address these constraints, we developed an time her helps someone innovative yam propagation technique using vine cuttings. In this method, cuttings, usually one to two nodes with leaves are taken from the lateral branches of immature healthy-looking vines before tuber enlargement, and planted into soil with carbonized rice husks (CRH).

Once the cuttings formed roots and shoots, they are transplanted to nursery beds where they are nurtured for 150 days. During this time they will produce mini tubers, which are then used as the planting material for the next crop.

We are testing this novel technique in a number of farmers’ fields in Nigeria’s north central Niger state. The technology has been extensively featured in a number of broadcast and print media in Nigeria, Japan and the UK, and some countries in sub-Saharan Africa and Oceania.

By reducing the use of ware tubers as seeds, more yams are made available to farmers for food or for sale. The technique also promotes faster multiplication and better and more uniform crop quality by introducing a break in the cycle of nematode infestation often associated with regular use of field-grown tubers as planting material.

Another advantage of this technology is that the rooting medium, CRH, could be obtained by farmers cheaply, even for free.

Previously, we developed another propagation method together with the National Root Crops Research Institute of Nigeria based on mini-setts: yam tubers are cut up into 20-25 g pieces and used to produce planting material for ware tuber production.

Compared to using whole tubers, mini-setts enable faster multiplication and lesser amount of planting material needed. The use of vine cuttings further improves on this pace of multiplication and reduces the amount of need planting material even more. The technology could address the need for faster and wider distribution of disease-free improved varieties to meet rising demand.

The research is funded by the Japanese government, the Sasakawa Africa Association, Tokyo University of Agriculture, and the International Cooperation Center for Agricultural Education, Nagoya University, Japan.

2009 Financial information

finance-imageFunding overview

Funding for 2009 was US$52.202 million, of which 92.7% came from CGIAR investors and 7.3% from other sources. Expenditure was US$50.821 million (net of indirect costs recovery of US$5.535 million), of which 81.2% was used for program expenses and 18.8% for management and general expenses.

The governments and agencies that provided the largest share of our funding in 2008 and 2009 are shown in Figure 1 (top 10 donors). Our 2008 and 2009 expenditures by CGIAR system priorities and program portfolio are shown in Figures 2 and 3, respectively; while the performance indicators, as prescribed by CGIAR, are reflected in Figure 4.

Figure 1. Funding: top 10 donors, 2008 and 2009

Top 10 donors, 2008 and 2009

Figure 2. Expenditure by CGIAR System Priorities, 2008

Expenditure by CGIAR System Priorities, 2008

Expenditure by CGIAR System Priorities, 2009

Expenditure by CGIAR System Priorities, 2009

IITA Investors, 2008 and 2009

IITA Investors, 2008 and 2009

Figure 3. Expenditure by IITA Program Portfolio: 2008 and 2009

Expenditure by IITA Program, 2008 and 2009

Figure 4. Performance Indicators: Financial Health

Performance indicators: Financial Health 2009

Our Board of Trustees

IITA’s Board of Trustees (BoT) is made up of 14 members and is responsible for ratifying policies, procedures, and programs of the institute. The following are the current members of the BoT:

Bryan Harvey
Plant Sciences Department
University of Saskatchewan

Barbara Becker
Managing Director
North-South Centre

Director General

Hans Joehr
Corporate Head of Agriculture

Anne Kathrine Hvoslef-Eide
Assistant Professor
Applied Biotechnology
Norwegian University of Life Sciences

Cees Karssen
Plant Physiologist
The Netherlands

Dean Lewis
United States

Paul Mbe-Mpie Mafuka
Faculté des Sciences Agronomiques
Gestion des Ressources Naturelles
Democratic Republic of Congo

Henri Maraite
Unité de Phytopathologie
Faculté d’ingénierie biologique, agronomique et environnementale
Université catholique de Louvain

Birger Møeller
Professor of Plant Biochemistry
Danish National Research Institute

Otaki Oyigbenu
Permanent Secretary
Federal Ministry of Agriculure and Rural Development

Emmy Simmons
USAID (retired)
United States

Nthoana Tau-Mzamane
Walter Sisulu University
South Africa

Yo Tiémoko
Director General
Centre National de Recherche Agronomique
Côte d’Ivoire

Verishima Uza
Vice Chancellor
University of Agriculture

Beauveria bassiana: a golden opportunity for vegetable farmers

Adult of Plutella xylostella, commonly known as Diamondback moth. Photo from Wikimedia Commons.
Adult of Plutella xylostella, commonly known as Diamondback moth. Photo from Wikimedia Commons.

One of the biggest threats to cabbage farming in West Africa is Plutella xylostella, commonly known as the Diamondback Moth (DBM). For years, DBM has been devastating both smallholder and commercial cabbage farms in the region, affecting incomes and market prices of the crop.

To address this, we developed and field tested a biopesticide based on the fungus Beauveria bassiana 5653 against DBM. Aside from effectively controlling DBM, cabbage yield in plots treated with Bba5653 was almost three times higher compared to plots treated with the insecticide bifenthrin or to untreated plots.

Songhai Center—a Private Voluntary Organization for training, production, research and development of sustainable agricultural practices—have been involved in the testing and highly recommends the product.

Bba5653 can control DBM on cabbage and its cousin kale, regarded as high-value cash crops. Compared to other vegetables such as carrot and lettuce, farmers say returns are higher with cabbage cultivation.

Cabbage damaged by DBM. Photo by Ignace Godonou, IITA.
Cabbage damaged by DBM. Photo by Ignace Godonou, IITA.

For the past few years, thousands of farmers in West Africa had to abandon cabbage production because of DBM. Consequently, market prices for African cabbage have jumped because of dwindling supplies.

The high costs of synthetic pesticides do not help either. The most common chemical pesticides—bifenthrin and deltamethrin—require about 19 applications within three months prior to harvest. The expense is prohibitive for most farmers.

Farmers, like Louis Awandjinou who has been cultivating the crop since 1986, have also observed that the chemical pesticides have been less and less effective against DBM over the years.

Alternatively, farmers have been using botanical pesticides, mostly extracts from the seed of the neem tree, against DBM and a wide range of other arthropod pests, but the approach has had limited success.

Used in integrated pest management, B. bassiana­-based biopesticide offers a cost-effective and environmentally-friendly solution to DBM. The fungus has a narrow range of target pests and persists in the environment with the ability to remain active for several months after initial application, B. bassiana could end the frequent application, high costs, and risks associated with the use of chemical pesticides. It could also preserve beneficial insects, and, by extension, biodiversity.

Advances in the biological control of the cowpea pod borer

Apanteles taragamae
Apanteles taragamae. Photo by Georg Goergen, IITA.

Ecological studies carried out at the World Vegetable Center (AVRDC) in Taiwan identified the parasitoid Apanteles taragamae as the most promising for controlling the legume pod borer Maruca vitrata in Africa. To test its effectiveness, our researchers in Benin imported A. taragamae under standard quarantine protocols and carried out experimental releases in Benin, Ghana, and Nigeria in 2007 on patches of wild vegetation including plants known to host the pod borer such as Lonchocarpus sericeus, Pterocarpus santalinoides, Lonchocarpus cyanescens, and Tephrosia spp.

Prior to these releases, we had studied the host searching capacity of A. taragamae using a 4 arm-olfactometer, and flowers of three different host plants: cowpea, Pueraria phaseoloides and the three Lonchocarpus sericeus. These studies revealed that A. taragamae uses kairomone-mediated host recognition at the short to medium range.

From as early as six months after the first releases and up until 2009, we conducted a series of surveys to monitor establishment of the parasitoid. Although we were not able to successfully recover the released parasitoid, we got indirect evidence of its establishment in the environment. We ruled out that interspecific competition with indigenous parasitoids exploiting M. vitrata larvae of the same age and on the same host plant could be the cause for this lack of evidence because we had conducted, just before the releases, elaborate competition studies which did not reveal any problems. Also, in its area of origin in Taiwan, A. taragamae coexists with similar parasitoid species found in Benin e.g. Phanerotoma sp. and Dolichogenidaea sp.

A Maruca vitrata larva. Photo by IITA.
A Maruca vitrata larva. Photo by IITA.

In Taiwan, however, A. taragamae is found prevalently on the cover crop Sesbania cannabina, which is difficult to grow in West Africa because of foliage beetles, particularly Mesoplatys sp. that completely defoliates the plant. We recently intensified our studies on African indigenous species of Sesbania that suffer less beetle damage, but so far there have been no signs of direct establishment. This is despite screenhouse experiments confirming the suitability of Sesbania species as feeding substrate for the pod borers and also as host for foraging parasitoids.

From 2007 onwards, we also started testing the newly-discovered Maruca vitrata Multi-Nucleopolyhedrosis Virus (MaviMNPV) found in Taiwan through collaborative studies with AVRDC. After a series of laboratory tests which confirmed the Taiwan results, we carried out host range studies to ascertain its specificity. Of the seven lepidopteran species tested (four Pyralids, two Noctuids, and one Crambid), none got infected by MaviMNPV applied on artificial diet. We then tested the virus in semi-natural condition using field cages with artificial infestations of M. vitrata larvae. Results showed a very high mortality of pod borer larvae (>95%) using standard concentrations comparable to those found in commercial formulation of entomopathogenic viruses (e.g. against the cotton bollworm Helicoverpa armigera).

Characteristic symptom of Maruca vitrata attack on cowpea. Photo by IITA.
Characteristic symptom of pod borer attack on cowpea. Photo by IITA.

In the Mono region of Benin, we discovered a few pod borer larvae with apparent signs of MaviMNPV close to the release sites of the parasitoids. This observation was important since we did not carry out open field experiments nor has MaviMNPV been found in West Africa prior to its introduction in 2007. We hypothesized that the parasitoid A. taragamae could have transmitted MaviMNPV to pod borer larvae.

To verify this, we deliberately infected pod borer larvae using three methods: ovipositor only, whole body without ovipositor, and through artificial diet. The parasitoid was able to transmit the virus to the larvae through all of the infection methods.

This finding was significant as the parasitoid could spread the virus without further intervention. This is also indirect evidence that A. taragamae is present in the environment, albeit in low levels, which cannot be detected by current sampling methods, or on yet unknown secondary host plants for M. vitrata. We are currently conducting collaborative studies in our virology lab in Ibadan to identify and ascertain the mechanisms of transmission, and duration of virus retention and transfer.

Publications & graduate research

A researcher inspecting cassava in vitro culture plantlets at the Genetic Resources Unit. Photo by Jeffrey Oliver.
A researcher inspecting cassava in vitro culture plantlets at the Genetic Resources Unit. Photo by Jeffrey Oliver.


In 2009, we produced 299 publications, which comprised of 181 journal articles, 17 books, 5 in-books, 20 conference proceedings, 12 technical reports, and 64 other publications. A total of 118 of the journal articles appeared in peer-reviewed journals that are listed in Thomson Scientific/ISI. The complete listing and details of these publications can be found in our online bibliography.

Graduate research

Individual training

This year, 99 new trainees (29% female, 71% male) registered for our various programs; 92 came from sub-Saharan countries, while the rest were from countries outside of Africa.

A total of 118 students (46% female, 54% male) had ongoing research training, with 31% conducting studies for their PhD’s, 32% working towards their MSc’s (or equivalent), 13% working towards their BSc’s, and 20% for other academic certificates and diplomas. The rest are staff of national research institutions that came for short-term training or to work alongside our scientists. One hundred and seven students came from 20 countries in sub-Saharan Africa, while 11 came from 7 countries in Europe, Central America, North America, and Asia.

Group training

Distribution of academic trainees 2009.
Distribution of research trainees, 2009.

We delivered over 195 group training courses in more than 300 locations in 13 countries across sub-Saharan Africa. Over 21,701 individuals (27% female, 73% male) participated in these courses. More than 50 of these activities were Training-of-Trainers involving NGOs, government extension, and farmer cooperative partners. These focused on crop management practices including IPM, agronomic management, and macro-propagation techniques.

Our other training activities covered extension, field/lab research skills, pest risk assessments, pest/pathogen diagnostics, collective marketing, agronomic practices, processing and utilization, statistical computing, vegetative propagation, lab safety, agribusiness, managing cooperatives, and participatory variety selection.

Our scientists & project managers

Some of our scientists during a video shoot as part of the multimedia communications training at R4D Week 2009. Photo by O Adebayo, IITA.
Some of our scientists at a video shoot, part of the multimedia communications training during R4D Week 2009. Photo by O Adebayo, IITA.

Abass, Adebayo Busura
Coordinator, Cassava Value Chain

Abdoulaye, Tahirou
Outcome/Impact Socio-Economist

Ajala, Oyewole S
Maize Breeder

Akwah, George Neba
CIALCA Associate Scientist

Alene, Arega D
Impact Economist

Asare, Richard
Cocoa Agroforester

Asiedu, Robert
R4D Director

Badu-Apraku, Baffour
Maize Breed, DTMA Project

Bandyopadhyay, Ranajit

Beed, Fen Douglas
Plant Pathologist

Biemond, Pieter Chris
Seed System Specialist

Boahen, Stephen
Legume Specialist

Boukar, Ousmane
Cowpea Breeder

Bouwmeester, Hein
GIS Specialist

Casey, John H
Manager, STCP

Chikoye, David
R4D Director

Cornet, Denis D

Coulibaly, Ousmane
Agricultural Economist

Coyne, Daniel Leigh

David, Soniia
Technology Transfer Specialist, STCP

Davis-Mussagy, Melba
Agroenterprise Development Specialist

Dubois, Thomas L M
Seed Systems Specialist

Dumet, Dominique Juliette
Head, Genetic Resources Center

Franco, Jorge

Gedil, Melaku A
Cassava Molecular Geneticist

Gockowski, Jim J
Agricultural Economist

Godonou, Ignace

Gyamfi, Isaac Kwadwo
Country Manager, STCP-Ghana

Hanna, Rachid
Entomologist/Biocontrol Specialist

Hauser, Stefan
Agronomist/Soil Physicist

Hearne, Sarah Jane
Plant Molecular Geneticist

Hoeschle-Zeledon, Irmgard
Coordinator, SP-IPM

Ihedioha, Onyema Damia
Agri-Processing Specialist

Ingelbrecht, Ivan
Head, Biotechnology Lab

Iyangbe, Charles
Agribusiness Development Coordinator

James, Braima D
Entomologist/Project Manager, UPoCA

Jonas, Mva Mva
Country Manager, STCP-Cameroon

Kamara, Alpha Yaya
Savannah Systems Agronomist

Kanju, Edward Eneah
Cassava Breeder/Pathologist

Kikuno, Hidehiko
Yam Physiologist

Kim, Dong-Jin D

Kulakow, Peter
Cassava Breeder/Geneticist

Kumar, Lava
Virologist (West and Central Africa)

Legg, James

Lorenzen, James H
Banana Breeder

Mahungu, Nzola-Meso
Coordinator, NPACI and IITA Cassava Project

Manyong, Victor A W
R4D Director

May-Guri, Seathre S
Senior Researcher

Maziya-Dixon, Busie
Crop Utilization Specialist

Menkir, Abebe
Maize Breeder

Muoki, Penina Ngusye
Food Technologist

Muranaka, Satoru
Crop Physiologist

Neuenschwander, Peter
Scientist Emeritus

Ngeve, Jacob Mbua
Cassava Breeder/Geneticist

Ntawuruhunga, Pheneas
Coordinator, SARRNET

Okafor, Christopher
Country Manager, STCP-Nigeria

Okechukwu, Richardson
Deputy Project Manager, UPoCA

Olaopa, Yewande S
Association Development Specialist

Onzo, Alexis

Ouma, Emily Awuor

Pay-Bayee, Macarthur M
Country Manager, STCP-Liberia

Rabbi, Ismail Yusuf
Molecular Genetics Postdoctoral Fellow

Rusike, Joseph J
Outcome/Impact Socio-Economist

Sartie, Alieu Mortuwah
Yam Molecular Geneticist

Sharma, Kamal
Researcher in Plant Pathogen Diagnostics

Sonder, Kai
GIS/Data Management Specialist

Tamo, Manuele
Legume Entomologist

Tarawali, Gbassay

Tefera, Hailu
Soybean Breeder

Tegbaru, Amare
Manager, PROSAB

Toko, Muaka

Tripathi, Leena

Van Asten, Petrus J A
Systems Agronomist

van Vugt, Daniel
Legume Agronomist

Vayssieres, Jean-Francois J

Vroh, Bi Irie B I

Yade, Mbaye
Regional Coordinator, SAKSS

Yapo, Robert Assamoi
Country Manager, STCP-Cote d’Ivoire

Yusuf, Ado Adamu
Soil Microbiologist

zum Felde, Alexandra
Banana/Plantain Agronomist