Category Archives: BecA-ILRI Hub

Goats housed in a kraal, Tanzania

Biosciences fund brings Tanzanian researcher one step closer to unravelling the genetic diversity of the Small East African goat

Goat production is among the foremost agricultural activities that sustain the livelihoods of millions smallholder farmers and pastoral and agro-pastoral communities in Tanzania. Majority of Tanzania goats (about 98%) are assumed to belong to the Small East African (SEA) breed, with very few belonging to other exotic dairy and meat goat breeds.

The Small East African goat breed is predominantly found throughout eastern Africa and parts of southern Africa. These goats have different tribal or local names and are mostly kept by pastoralists in the rural areas, agro-pastoralists and mixed (crops-livestock) farmers for meat. Their coat produces good quality leather. Some of the valuable characteristics of these goats are a tolerance to heartwater (an endemic tick-borne disease of ruminants), worms and other diseases commonly found in East Africa, such as mange. They are small (they range in weight between 20 and 45 kgs), agile and active goats whose colour ranges from pure white, pure brown to pure black with various intermixes of the three colors.


A young boy herds SEA goats in Tanzania

But different agroecological zones result in differentiations in the goats’ adaptive nature. SEA goats in Tanzania have not been fully characterized, and as a result, there is no breed- or strain-specific information on their genetic variability or uniqueness. Today, it is still unclear whether the indigenous goats of Tanzania are one breed (SEA) or if they fall under different strains or ecotypes. Additionally, the performance and adaptive attributes of the SEA goats kept in the country are still unknown.

Tanzanian farmers have made numerous efforts to crossbreed SEA goats in an attempt to improve their productivity, an activity that could prove more harmful than helpful if not checked. Crossbreeding by farmers without understanding the goat genetic resources could lead to loss of some of the unique features of these goats. On the other hand, understanding goat genetics has the potential to increase SEA goats’ milk and meat productivity and create sustainable development of goat farming in the country.


A woman milks an SEA goat belonging to the Pare Doe strain

Athumani Nguluma, a senior research officer at the Tanzania Livestock Research Institute (TALIRI), and a former Biosciences eastern and central Africa – International Livestock Research Institute (BecA-ILRI) Hub Africa Biosciences Challenge Fund (ABCF) fellow, is studying the genetic diversity of SEA goats in Tanzania. His goal is to better understand this important goat breed so that he can contribute to a clearer understanding of its population genetic structure and unique genetic features. This knowledge will be vital in designing SEA breed improvement and conservation programs, which could solve the low meat and milk productivity problem of the local goats that plagues Tanzanian farmers thereby considerably improving household income and bringing other socio-cultural benefits.

At TALIRI, Nguluma is working with the organization responsible for coordinating research in Tanzania including small ruminant research, which is where Nguluma was exposed to previous research on SEA goats and his interest was piqued. While studying for his PhD, he worked on the characterization of SEA goats, but due to insufficient funding, his assessed only a few subpopulations of the breed and identified only a few microsatellite markers of the breed’s genome.

Receiving the ABCF fellowship broadened Nguluma’s research from what he had initially hoped to do. His study, which has been ongoing for a year, is focused on assessing the diversity of goats in the major agro-ecological zones of Tanzania. His research methods include on-farm collection of goat blood samples and a cross-sectional research design through farmer interviews to gather information about the goats breeds in the country and their production environment. So far, he has obtained phenotypic and maternal genetic variation data of goats from 11 out of 26 regions in the country.

Nguluma appreciates the role of the BecA-ILRI Hub in equipping him with the skills to do this work. ‘Before coming to BecA-ILRI Hub my knowledge and skills on molecular genetics and genomics was low. I have since been exposed to state-of-the-art molecular labs and the technical knowhow in molecular research. I have also gained modern bioinformatics skills and access to important software for my research.’


The Tanzanian Ujiji Doe strain from the SEA breed

The next steps in his research include data analysis, report writing and publishing his findings. He will also conduct a comparative genomic study of the country’s goat populations to better understand the uniqueness of particular breeds. Later he will carry out whole sequencing of their genetic code so he can develop markers for improvement to boost their productivity. 

While at BecA-ILRI Hub, he was supervised by Roger Pelle. At TALIRI, he’s supervised by S. W. Chenyambuga and Zabron Nziku from TALIRI.

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Researcher using skills gained at BecA-ILRI Hub to hasten adoption of improved Brachiaria grass varieties in Tanzania

With an area of 885,800 km2 and a population of 58,458,191 people, Tanzania is one of the largest and most populous countries in Africa. Crop and livestock farming is the main source of livelihood for most Tanzanians. The country’s large livestock population includes 25 million cattle, 16.7 million goats, and eight million sheep.

The main source of feeds for livestock in Tanzania is natural pastures, which are found in the country’s vast rangelands. But these feed sources are often of poor quality and insufficient, especially in the dry seasons. Additionally, conversion of natural pasture into crop production and non-agricultural use areas, and the degradation of pasture due to overgrazing and poor management have reduced the feed available to the country’s livestock.

One step towards addressing the shortage of quality animal feeds in Tanzania is by establishing the available alternative feed resources. Walter Mangesho, a senior livestock research officer at the Tanzania Livestock Research Institute (TALIRI) and a former Africa Biosciences Challenge Fund (ABCF) fellow at the Biosciences eastern and central Africa-International Livestock Research Institute (BecA-ILRI) Hub, is assessing the Brachiaria grass ecotypes in Tanzania and their morphological and genetic characterizations.


Mangesho collects morphological data (measuring culm thickness) of one Brachiaria ecotype. Standing is TALIRI Tanga field research assistant Salvatory Kavishe recording data

In addition to establishing the types of Brachiaria grasses in the country; Mangesho’s research aims to improve selected Brachiaria grass cultivars, which have high biomass production potential, are nutritive to livestock and resilient to climate change. His goal is to avail the improved Brachiaria varieties to smallholder farmers in Tanzania who will use them as feed to improve the productivity of their animals. ‘I am determined to work towards solving the major livestock challenges in Tanzania, which include a shortage of quality feeds,’ he said

His research, which started in Dodoma, has so far identified and collected 142 Brachiaria ecotypes from 10 regions of Tanzania. These ecotypes are now maintained in a field at TALIRI in Tanga, Tanzania. All the ecotypes were characterized for morphological characteristics and genetic diversity. A subset of the ecotypes with superior phenotypes have been selected and are currently being multiplied for further evaluation.

‘While at the BecA-ILRI Hub, I worked with a team of highly-qualified researchers, mentors and trainers who helped me in molecular biology and genomics research that I had no prior experience with. They strengthened my morphological data collection skills,’ Mangesho remembers of his time as an ABCF fellow at BecA-ILRI Hub.


Mangesho trains on DNA extraction at BecA-ILRI Hub

He was supervised by BecA-ILRI Hub’s Sita Ghimire, Cathrine Ziyomo and Nasser Yao. Jonas Kizima from TALIRI and Angelo Mwilawa from Ministry of Livestock and Fisheries, Tanzania also supervised his genomic and morphological data collection while at the hub.

‘I hope to start multi-location trials in December 2020, once the Brachiaria cultivars are ready,’ remarks Mangesho about his next plans for the near future.

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Africa Biosciences Challenge Fund fellow conducts inventive goat genetic diversity research in DR Congo

Goats are among the most common farm animals in developing countries. Africa is home to about 35% of the world’s goat population (FAO 2016). They play an important socio-economic, nutritional and cultural role in rural households. An important indicator of goats’ adaptation to environmental conditions is their reproductive efficiency.

DR Congo has three major agro-ecological zones: the alluvial basin in the northeast and the central part; savannah in the central, western and the southeast; and the high-altitude volcanic mountains in the east of the country. More than 4,082,624 indigenous goats are spread throughout these agro-ecological zones.


Herd of goats

In the Democratic Republic of Congo, goats are the second most domesticated species after chicken. Goats make up between 30% and 60% of the country’s total livestock numbers. The country hosts three major breeds: the small goat, dwarf goat and Kasai goat. Congolese goat farmers raise and breed goats for meat production and commercial transactions, contributing up to 72% of households’ income in rural areas in the country. The productivity of African’s indigenous goats is low, and little is documented on the genetic diversity, production system and distribution of goats in DR Congo.

Patrick Baenyi, an Africa Biosciences Challenge Fund (ABCF) fellow from the Evangelical University in Africa, DR Congo, undertook a survey on 202 goat farmers in the country to identify typology, production management and critical traits considered in goat selection by farmers in three agro-ecological zones — South Kivu, Tshopo and Kinshasa. In his pioneering research, he collected phenotypic data and used phenotypic and molecular markers, that are the basis for animal genetic diversity studies, to characterize goat genetic resources.

The survey revealed that goats in the three zones were clustered into breed clusters, grouped into small goat and dwarf goat, mostly characterized by a black coat colour and curved horn. The clusters were further distinguished by their reproductive traits (i.e. the number of kids per gestation period, such as twins or triplets) and the total number of kids per goat’s lifespan.


Baenyi and a member of his team collect a blood sample from a goat in Tshopo, DR Congo

Baenyi’s study was an important first step towards goat breeding in the country and aids decision-making on goat genetics improvement in the country. Its findings suggest that molecular characterization by sequencing and genotyping should be considered by animal breeders to clarify the physical differences in goat breeds that were observed and to identify whether these differences are genetic or adapted from environmental influence. A good understanding of this genetic characterization is useful in designing effective strategies for managing, improving and conserving domesticated animal resources.

‘Working with the Biosciences eastern and central Africa-International Livestock Research Institute (BecA-ILRI) Hub reinforced my skills in conducting genetics research and showed me the value of collaborating with other researchers and sharing my findings with the public. I was also trained in bioinformatics and proposal writing and I have continued with the invaluable mentorship relationships that started during my time at the hub,’

says Baenyi.

He is currently working under the supervision of ILRI’s Roger Pelle and his and is studying for his PhD in animal genetics and breeding at the University of Nairobi.

Research at BecA-ILRI Hub supports vaccine development policy in Kenya

By Jane Githinji, assistant director of veterinary services, Kenya and ABCF alumnus

Jane githinjiAs head of the virology laboratory at the Central Veterinary Laboratories in the Directorate of Veterinary Services (DVS) in Kenya, my responsibilities include laboratory surveillance, and confi rmation and reporting of animal viral diseases. My reports form the basis upon which disease control strategies are developed. It is, therefore, of the utmost importance that these reports refl ect the true picture of the disease situation in the country, from which appropriate disease control policies and strategies can be derived.

Like in most developing countries, poultry farming in Kenya is mainly in the hands of the smallholder rural poor, mostly women and young people, and is usually the only livelihood source for smallholder farmers. Outbreaks of infectious viral diseases that cannot be treated pose a major constraint on poultry production. Vaccination is the recommended method of control for these diseases. But vaccines do not always prevent occurrence of a disease.

The apparent failure of vaccines to protect chicken from infectious bursal disease (IBD) got me interested in understanding the cause of the disease despite prompt vaccinations by farmers (IBD causes immune suppression, making chicken more prone to other infectious diseases). I wanted to improve my understanding of the epidemiology of IBD in Kenya, starting with the comparative molecular characterization of the circulating viruses with the currently used vaccine virus strains.

The facilities available at the central veterinary laboratory are suitable for carrying out basic molecular analysis. However, to undertake more advanced molecular research required to gain a better understanding of IBD viruses circulating in Kenya, I needed access to the facilities at the BecAILR Hub. Under the mentorship of the BecA-ILRI Hub scientists, in a very conducive research environment as an ABCF fellow, I learned many skills, including sequence editing and analysis, primer design, scientific paper writing and communicating science to non-scientists. These crosscutting skills will be very useful in improving my diagnostic capacity, and ultimately, scientific data collection for policy development at the DVS.

Based on the feedback and recommendations I gave to the DVS director, I am confident my research findings will form the basis for developing effective IBD control strategies, including diagnosis, vaccination, hatchery surveillance and certification, IBD vaccines registration and vaccine production. Implementation of such strategies will have far reaching impacts on poultry production, poverty alleviation, nutritional security, economic empowerment for women and young people, and self-employment. Reducing antimicrobial residues in poultry products will also contribute to a reduction in antimicrobial drug resistance in humans.

With my newly acquired skills, I will be able to contribute more to livestock research: science, technology and innovation. I am a better mentor to young people, a better leader and manager, a more fulfilled person, and, above all, an asset to my country. My time as an ABCF fellow marked the beginning of what I believe will be a journey full of discoveries, networking, research development and fulfilment.

chicken and chics

Read more about the bioscience research and innovations that underpin development outcomes in the BecA-ILRI Hub 2016 Annual Report.

Supporting African-led agricultural research to drive economic growth – Part 2

Investigating the role of bushmeat in the transmission of zoonotic diseases in Tanzania

Research conducted by the Biosciences eastern and central Africa-International Livestock Research Institute (BecA-ILRI) Hub in collaboration with National Health Laboratory of the Tanzania Ministry of Health and Social Welfare; Nelson Mandela African Institution of Science and Technology (NM-AIST); Sokoine University of Agriculture; Tanzania National Parks; Tanzania Wildlife Research Institute; Frankfurt Zoological Society; and Pennsylvania State University.

An outcome of the BecA-ILRI Hub’s Swedish funded initiative to strengthen infrastructural and human capability at NM-AIST, was the awarding of a grant to the institution by the US Defense Threat Reduction Agency.

The NM-AIST School of Life Sciences and Bioengineering and a consortium of partners including the BecA-ILRI Hub received a grant to investigate the role of bushmeat in the transmission of six pathogens between animals and humans in Tanzania.

An interdisciplinary and multi-institutional team of scientists from Tanzania, Kenya and the US are using state-of-the-art techniques to map the distribution of anthrax, ebola, marburg and monkeypox viruses as well as Brucella and Coxiella in bushmeat in Tanzania. The team assesses the biological risk and potential for impact on human health from these diseases.

The BecA-ILRI Hub provides capacity building, expertise and technology for the microbiome component of the project using the genomics platform. During a week-long workshop facilitated by the BecA-ILRI Hub at NM-AIST, Francesca Stomeo provided training on the theory and practice of the genomics pipeline to be used in the project.

Read more about the bioscience research and innovations that underpin development outcomes in the BecA-ILRI Hub 2016 Annual Report.

bushmeat

Supporting African-led agricultural research to drive economic growth – Part 1

Scaling up the use of Brachiaria grass as a key forage in Africa

Research implemented in Kenya and Rwanda by the Biosciences eastern and central Africa-International Livestock Research Institute (BecA-ILRI) Hub and national partners — the Kenya Agricultural and Livestock Research Organization (KALRO) and  Rwanda Agriculture Board (RAB)

On-farm evaluations in Kenya and Rwanda have confirmed that the use of Brachiaria grass extends forage availability for livestock by up to three dry months. These evaluations also confirmed previous observations of increases in milk production and weight when cattle are fed on Brachiaria grass. Over 6,000 farmers in both countries are growing the four best-bet Brachiaria varieties (Basilisk, MG4, Piatã and Xaraés), which were identified through the use of a participatory approach with key stakeholders. These varieties are being concurrently scaled out in Kenya and Mali by the Accelerated Value Chain Development (AVDD) dairy project, funded by the United States Agency for International Development (USAID) Feed the Future Initiative. There is growing interest and a push to adopt Brachiaria grasses in other countries including Botswana, Cameroon, Mozambique, Namibia and Somalia.

This research has identified potentially beneficial bacteria that occur naturally within the grass (bacterial endophytes). The endophytes could be useful: increasing production of hormones that regulate: plant growth and boost biomass production in Brachiaria; improving soil nutrient solubility and soil fertility; enhancing drought tolerance; and improving the overall health of the grass. These endophytes are currently being evaluated under greenhouse conditions for their ability to confer drought tolerance to Brachiaria.

To ensure the transfer of technologies to national programs, seven researchers from five East African countries were trained on forages biotechnology through the Brachiaria program. After periods of between six and nine months at the BecA-ILRI Hub the NARS researchers returned to their home institutions with transferable skills acquired through the training. An in-depth external review of the program concluded that it has made significant contributions to the improvement of forage availability and livestock productivity in the aforementioned program countries.

Read more about the bioscience research and innovations that underpin development outcomes in the BecA-ILRI Hub 2016 Annual Report.

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Driving Africa’s agricultural development by enabling biosciences innovations

AR 2016 reportIn 2016, the Biosciences eastern and central Africa–International Livestock Research Institute (BecA-ILRI) Hub celebrated 15 years as a centre for excellence for agricultural research. Against a backdrop of renewed impetus for innovation in agricultural research for development (AR4D) in Africa, BecA-ILRI Hub and its partners showcased their joint achievements in responding to the Science Agenda for Agriculture in Africa (S3A)— leveraging science in an agriculture-led social and economic transformation. The event also offered us an opportunity to acknowledge our donors, whose support has made these accomplishments possible.

Research facilitated by the BecA-ILRI Hub drives the bioscience innovations that underpin development outcomes. The success of the climate-smart Brachiaria program in developing technologies that are readily adapted by farmers has generated a demand for their scaling-up. Strategic partnerships, for instance with the North Carolina State University (NCSU)—leveraging the human resource of advanced research institutions—have enabled groundbreaking work in tackling the devastating cassava mosaic disease, potentially increasing yields in what is a staple crop for over 250 million people in Africa.

Through the Africa Biosciences Challenge Fund (ABCF) fellowship program, up and coming research fellows from national agricultural research systems (NARS) have contributed to the formulation of evidence-based agricultural policies. For instance, seminal work on maize and food safety has provided a clearer picture of the interventions required throughout the value chain in Rwanda and research into chicken vaccines has supported the elaboration of policies guiding the production of vaccines for infectious bursal disease in Kenya. Moreover, the establishment and support of communities of practice (CoPs) for ABCF alumni has enabled the development of a comprehensive regional approach to the tackling of key livestock and crop research challenges.

In step with technology advances, the BecA-ILRI Hub launched the Integrated Genotyping Service and Support (IGSS) platform to enhance efficiency and precision in plant and livestock breeding, as well as quality seeds assessment. In research led by the International Maize and Wheat Improvement Center (CIMMYT), application of this new technology has improved understanding of the genetic basis for resistance to maize lethal necrosis (MLN). The ongoing upgrading of the BecA-ILRI Hub’s technology platforms is fast-tracking research within the regional NARS and reducing the need for scientists to leave Africa to do their work.

Working to shape to continent-wide processes, BecA-ILRI Hub staff joined CGIAR research scientists, policymakers, and representatives of higher education networks and the private sector at a workshop to develop the concept of the the African Agricultural Research Programme (AARP). AARP is an initiative led by the Forum for Agricultural Research in Africa (FARA) to strengthen the continent’s agricultural research systems for increased productivity, profitability and sustainability. As part of our 2018–2023 strategy, the BecA-ILRI Hub will seek to play a leading role in the application of and support for biosciences in the region. A landscape survey confirmed the comparative advantage of the BecA-ILRI Hub as an important regionally-valued bioscience facility. It identified opportunities to enhance our role in helping set the bioscience agricultural research agenda, as well as an advocate for the government funding of NARS work in bioscience technologies and services.

The coming year will, therefore, be characterized by engagement with key stakeholders to guide the development of our new five-year plan. We remain committed to helping Africa use biosciences as a means of transforming agriculture, bridging the gap between population growth and agricultural productivity on the continent. To the readers of this report, we hope you will accompany us on this grand AR4D journey in Africa. To our many partners and donors, thank you for your support.

Jimmy Smith Director General, ILRI

Jimmy Smith
Director General, ILRI

Appolinaire Djikeng Director, BecA-ILRI Hub

Appolinaire Djikeng
Director, BecA-ILRI Hub

 

 

 

 

 

 

 

 

 

 

You can download the full 2016 Annual report: http://hdl.handle.net/10568/83016

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Forging research partnerships between the BecA-ILRI Hub and Earlham Institute

By Joyce Nzioki, Research associate-bioinformatics at the Biosciences eastern and central Africa-International Livestock Research Institute (BecA-ILRI) Hub

Joyce Nzioki (left) and Fracnesca Stomeo at the Earlham Institute in Norwich, UK

Joyce Nzioki (left) and Fracnesca Stomeo at the Earlham Institute in Norwich, UK

From 1-13 July 2017, capacity building scientist Francesca Stomeo and I visited the Earlham Institute in Norwich, UK. Our mission was to explore ways of strengthening the budding partnership between the BecA-ILRI Hub and Earlham Institute as well as to gain knowledge that will improve the Hub’s genomics and bioinformatics platform.

We had an intense one and a half week of meetings and interaction with the institute’s genomics and bioinformatics specialists, with guidance of our hosts Anthony Hall, head of plant genomics and post-doctoral scientist Jose de Vega. There was much to learn about different aspects of genomics and bioinformatics, particularly in terms of lab and bioinformatics protocols and systems.

It was very exciting to share experiences on our research and training opportunities, and make potential connections for joint activities in the near future. The discussion we had with the project leader-bioinformatic algorithms, Bernardo Clavijo was invaluable in planning for the BecA-ILRI Hub annual advanced bioinformatics workshop that will take place in October this year. I am really glad that Clavijo will be among the trainers for that workshop.

Discussions on work by national agricultural research system (NARS) research fellows conducted at the BecA-ILRI Hub highlighted potential areas of collaborative research to enhance food safety and security in Africa including: improved conservation of fish, understanding drug resistance in Salmonella, plant transformation and exploiting various under-utilized African crop species. We were also challenged to consider introducing the portable Oxford Nano Pore sequencing technology to serve our partners who may not be able to purchase the bigger high through put sequencing machines.

From the visit to Earlham Institute, I saw a clear need for improved bioinformatics capacity to fulfil the potential of modern biosciences in Africa. Bioinformatics training—a key component of the BecA-ILRI Hub’s remit—is central to the training conducted at the Norwich Research Park (NRP), of which the Earlham Institute is a partner. We had fruitful discussions on strategies to empower a cohort of bioinformaticians in Africa with hands-on training in 2018.

I look forward to many joint research and training activities with scientists in Earlham Institute starting with the bioinformatics workshop in October!

The bioinformatics lab at the Earlham Institute in Norwich, UK

The sequencing facility at the Earlham Institute in Norwich, UK

About the author:
Joyce Nzioki is a bioinformatics analyst providing bioinformatics support to various on-going genomics projects at the BecA-ILRI Hub. She holds a Masters in Bioinformatics from Rhodes University in South Africa and a Bachelor’s degree in Biomedical Technology from the University of Nairobi, Kenya. Through her MSc studies, she gained skills in working in a Linux environment, Python programming, mathematical and statistical applications to biology and bioinformatics (R and Matlab), structural bioinformatics, genomics and proteomics.

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Exploring biological control of crop disease through plant-pest interactions

Aphids, leafhoppers and whiteflies are responsible for the spread of diseases causing significant crop yield losses globally. On 5 July 2017, the Biosciences eastern and central Africa-International Livestock Research Institute (BecA-ILRI) Hub hosted a symposium to explore ways in which the knowledge of plants, disease-causing organisms and their vectors can be used to combat devastating crop diseases in Africa.

Stephen Runo of Kenyatta University (left) with JIC scientists Beccy Corkill, Olu Shorinola and Sam Mugford (photo JIC/Matt Heaton)
Stephen Runo of Kenyatta University (left) with JIC scientists Beccy Corkill, Olu Shorinola and Sam Mugford (photo JIC/Matt Heaton)

In sub Saharan Africa, the aphid-transmitted bean viruses—bean common mosaic virus (BCMV) and bean common mosaic necrosis virus (BCMNV)—cause up to 100 percent losses for smallholder bean farmers. Growers of cassava—a staple food for over 250 million people— experience losses of up to 23 million tonnes annually across Africa due to disease caused by whitefly-transmitted Cassava mosaic viruses.

In the face of increased regulations on the use of pesticides, a better understanding of the plant-microbe-vector interactions could lead to the development of urgently needed bio pest-controls. The July forum brought together researchers from the BecA-ILRI Hub, Kenyatta University, International Institute of Tropical Agriculture (IITA), Auburn University and North Carolina State University based in Africa; and the John Innes Centre (JIC) from UK.

From left to right: Josiah Mutuku (BecA-ILRI Hub), Olu Shorinola (JIC), Steven Runo (Kenyatta University), Beccy Corkill (JIC) and Sam Mugford (JIC) at the BecA-ILRI Hub greenhouses (photo: JIC/ Matt Heaton

From left to right: Josiah Mutuku (BecA-ILRI Hub), Olu Shorinola (JIC), Steven Runo (Kenyatta University), Beccy Corkill (JIC) and Sam Mugford (JIC) at the BecA-ILRI Hub greenhouses (photo: JIC/ Matt Heaton

The symposium was held under the Alliance for Accelerated Crop Improvement in Africa (ACACIA) initiative—a new initiative established to harness diverse research efforts for hastened crop improvement in Africa.

Read full story: Deciphering Plant-Insect Interactions on the ACACIA website.

Read about the ACACIA initiative: New initiative to accelerate crop improvement for food security in Africa

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Growing climate-smart Brachiaria in Rwanda: BecA-ILRI Hub project to improve livestock production in East Africa

In the ‘Land of a thousand hills’ where the largely steep landscape  has led to severe erosion, finding sufficient feed to support the growing dairy industry has been a major challenge to smallholder farmers.

However, a visit to farmers in Eastern and Southern provinces of Rwanda during the country’s dry season in July revealed that the climate smart Brachiaria grass—or ivugbwe as it is known locally—has the potential to extend forage availability throughout the year.

Rwandan dairy farmers have been participating in a research project to assess the performance of best bet varieties of Brachiaria grass for different agro-ecological regions in Rwanda. The Swedish funded project on ‘Climate smart Brachiaria grass to increase livestock production in East Africa’ was led by the Biosciences eastern and central Africa-International Livestock Research Institute (BecA-ILRI) Hub and implemented in collaboration with the Rwanda Agriculture Board (RAB).

In this 5-minute video, the farmers talk about why Brachiaria grass has quickly become a favourite forage for their livestock.

Read original article on RAB website: Rwanda dairy farmers praise the climate smart ‘Ivugbwe’ grass