Africa looking to strategic partnerships to rein in food and nutrition insecurity

A child feeds on orange fleshed sweet potato in Central Uganda – Image credit ‘Winnie Nanteza/NARO-Uganda’

World hunger continued to rise for the third consecutive year according to the UN’s Food and Agriculture Organization (FAO)’s latest report. The data identifies climate variability as one of the major contributing factors to this worrying statistic. The intricate relationship between climate change and food security culminates in a major challenge that has rattled individuals, organisations and governments alike for decades. In the coming decades, Africa—which faces the biggest food security challenge in present times—will need more strategic partnerships to unlock its food security potential.Nearly one in every nine people—a significant proportion of whom live in Sub-Saharan Africa—go to bed hungry every night. So significant is this challenge that the United nations lists ending hunger, achieving food and nutrition security and promoting sustainable agriculture by 2030 second of its 17 Sustainable Development Goals (SDGs).

It is a daunting challenge made worse by an exploding global population set to hit 9 billion by 2050. Nonetheless, governments and other stakeholders worldwide are drawing inspiration from the fact that, despite the increases of the past three years, hunger overall has reduced by almost half in the past two decades. This has been made possible through deliberate efforts to increase agricultural production with minimal environmental impact.

Contemporary Agricultural Science Technology and Innovations (STIs) are pivotal to increasing agricultural production, food security, and promoting economic growth in Africa. However, realizing these aspirations greatly depends on leveraging the synergistic capabilities of the diverse actors within the sector towards building stronger partnerships and increased accountability for greater impact.

The nature of Agricultural Research for Development (AR4D) paradigms around the world is rapidly evolving, with new technologies constantly emerging and making the agricultural sector more knowledge intensive and innovations driven. In addition, the role of the private sector in agricultural R&D is increasingly more prominent, with Public-Private Partnerships (PPPs) being touted as an ideal model for accelerating technology transfer, commercialization, and delivery of research outputs to end-users for optimal research impact. Innovative partnerships between the public and private sectors are especially important for attracting investments and financing innovative solutions for agriculture in developing nations.

To drive this innovative and responsive research agenda, scientists globally are increasingly coming together in collaborative partnerships to share resources towards ensuring that the world will be able to feed nine billion people by 2050.

Among these is the Community Network for African Vector-Borne Plant Viruses (CONNECTED)—a Vector-borne Disease Network awarded to the University of Bristol—which held its Africa Launch Conference  in May 2018. The network—which is closely involved with the Cabot Institute—aims inter alia to build a sustainable network of multi-disciplinary international scientists, to deliver solutions to devastating crop diseases.
 

Participants at the CONNECTED Network Africa Launch, May 2018

Three months on, and the Network is already making good on its promise. Following the first CONNECTED pump prime funding call soon after the Network’s Africa launch, research funding grants have been awarded to Network members working in African and European research institutions in classic triangular collaborations to achieve the ideals of the Network.

In August 2018, global science leaders congregated in Durban, South Africa for the inaugural Bio Africa convention. The conference provided opportunities to build capacity and drum up support for increased investment in, and support for Africa’s growing biotech industry. It is hoped that networks built there will enrich the implementation of past and existing Africa-led initiatives for growth and sustainable development, especially in the bio-economy sector.

While food is an easy topic to get people involved with, rising concerns about some aspects of agricultural technology bring unique dynamics to this area. A July 25 ruling by the European Court of Justice imposed exacting regulatory restrictions on the use of gene editing in crop improvement. This adds to existing regulatory stalemates—mostly in Europe and Africa—blocking the use of products of modern agricultural technologies such as genetic engineering and gene editing to deliver important crop varieties to the world’s most vulnerable people.

In Uganda for instance, genetically modified biofortified and bacterial wilt resistant bananas, and blight resistant potatoes remain locked up in confined field trials due to the absence of an enabling regulatory environment for commercialisation. Research is on-going—using genetic engineering—on virus resistant cassava, insect resistant and drought tolerant maize, and nitrogen use efficient rice among other key food security crops.

The ebb and flow of global politics and science remains a determinant factor in whether or not agricultural STIs can contribute to ending hunger by 2030 per the SDGs. Cognizant of the constraints new breeding technologies are facing to deliver impact, initiatives like Uganda Biosciences Information Center (UBIC) have been established to support the stewardship process to ensure that key agricultural technologies reach the people that need them most.

This is achieved through creating and raising awareness of modern agricultural biosciences and biosafety, to facilitate balanced, fact-based and objective discourse on modern biosciences in Uganda and beyond. Elsewhere, the Open Forum on Agricultural Biotechnology (OFAB), International Service for Acquisition of Agri-biotech Applications (ISAAA) and Cornell Alliance for Science to mention but a few, are championing the same cause at regional and global levels.

In many ways gentle calls to action, such initiatives complement the millions of voices highlighting the global food challenge and imploring all humanity to spring to action to ensure that everyone has a seat at the (dining) table.

Policy coherence and coordination among different actors to end hunger remains key to delivering much needed solutions to global food and nutrition security. To end hunger, targeted steps must be taken to help people access the tools they need to create agricultural prosperity and progress. But we can’t just hope and pray, we have to take action—and Africa seems to be beginning to do just that!

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This blog was written by Joshua Raymond Muhumuza, CONNECTED Network member and Outreach Officer at the Uganda Biosciences Information Center (UBIC).

Saying goodbye and reflecting on lessons from the field

Last week I said goodbye to the National Crops Resources Research Institute (NaCRRI) where I have spent the last three months learning about Cassava brown streak disease (CBSD). I’m currently in the second year of my PhD at the University of Bristol, where I’m researching how CBSD viruses cause symptoms, replicate and move inside plants.

Cassava is a staple food crop for approximately 300 million in Africa. However cassava production is seriously threatened by CBSD, which causes yellow patches (chlorosis) to form on leaves and areas of tubers to die (necrosis), rot and become inedible. CBSD outbreaks are currently impacting on the food security of millions of cassava farmers in east Africa and it appears to be spreading westward, threatening food security in many countries.

I decided that I wanted to experience the problem for myself, see the disease in the field, meet the farmers affected and understand the different solutions. I am so pleased that I decided to visit NaCRRI; a government institute, which carries out research to protect and improve production of key crops, including cassava. The focus is on involving farmers in this process so that the best possible varieties and practices are available to them. Communication between researchers and farmers is therefore vital, and it was this that I wanted to assist with.

When I arrived I was welcomed so warmly, and was immediately part of the team. The root crop team leader Dr. Titus Alicai came up with a whole series of activities to give me a real insight into CBSD. I was invited to the field sites across Uganda, where I got to see CBSD symptoms in the flesh! I assisted with the 5CP project, which is screening different cassava varieties from five East and Southern African countries for CBSD and Cassava mosaic disease (CMD) resistance across different agro-ecological zones. I helped to score plants for CBSD symptoms. The researchers thought I was bit strange, getting very excited and taking lots of photos.

Main insight: complex and dynamic CBSD situation

The main insight I’ve gained is that the situation is both complex and dynamic. Different cassava varieties respond differently to CBSD infection, some plants show strong symptoms on the leaves and nothing in tubers, and other varieties show the opposite. Symptoms also depend on environmental conditions, which are unpredictable.

The whiteflies which carry viruses are also complex, and are expanding into new areas and responding to changing environmental conditions. There are also different viral strains found across different areas, and viral populations are also continually adapting.

Learning about solutions

It has been fascinating to learn how NaCRRI is tackling the CBSD problem through screening different varieties in the 5CP project, breeding new varieties in the NEXTGEN project, providing clean planting material and developing GM cassava.

Saying goodbye to new friends: Dr. Titus Alicai (NaCRRI root crops team leader), Phillip Abidrabo (CBSD MSc student) and Dr. Esuma Williams (cassava breeder)

And there’s the human element…

In each of these projects, communication with local farmers is crucial. I’ve had the opportunity to meet farmers directly affected, some of whom have all but given up on growing cassava. I’ve learnt a lot about how NaCRRI is constantly engaging farmers and involving them in solutions to the CBSD problem.

Challenges

Communicating has not been easy for me, as there are over 40 local languages. I’ve really had to be adaptable and learn from those around me. For example, in the UK we like to email the person sat next to us, whereas in Uganda you really have to talk to people to hear about what’s going on. This is all part of the experience and something I’m hoping to bring back to the UK!

I’ve had some funny moments too, during harvesting the Ugandans couldn’t believe how weak I was. I couldn’t even cut one cassava open!

Real world reflections

I’m going to treasure my experiences at NaCRRI. The insights into CBSD are already helping me to plan experiments, with more real-world applications. I can now see how all the different elements of the disease (plant-virus-vector-environment-human) join up and interact, something you can’t learn from reading papers alone!

Working with the NaCRRI team has given me the desire and confidence to collaborate with an international team. I’ve formed some very strong connections with people here and hope to have discussions about CBSD with them throughout my PhD and beyond. This will help make our research more relevant to the current situation. Above all, I’ve learnt the importance of getting out of the lab to experience and learn from what is happening in the field.

 

Thank you!

I would like to thank: Dr. Titus Alicai for welcoming me into the NaCRRI team and providing me with so many valuable experiences; the whole of the NaCRRI team for their generosity; my supervisors: Prof. Gary Foster and Dr. Andy Bailey for supporting my trip and my funders: Biotechnology and Biosciences Research Council, the Cabot Institute (University of Bristol), the British Society for Plant Pathology and the Society for Experimental Biology for supporting my internship.

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This blog has been written by University of Bristol Cabot Institute member Katie Tomlinson from the School of Biological Sciences.  Katie’s area of research is to generate and exploit an improved understanding of cassava brown streak disease (CBSD) to ensure sustainable cassava production in Africa.  This blog has been reposted with kind permission from Katie’s blog Cassava Virus.

 

Katie Tomlinson

More from this blog series:  

Blog 1: Getting ready to go… cassava virus hunting!
Blog 2: Week one: Settling in to Ugandan life
Blog 3: Learning the ropes
Blog 4: Clean cassava to solve brown streak problem?
Blog 5: Taking a trip to the cassava field!
Blog 6: Using GM to fight cassava brown streak disease
Blog 7: Talking sweet potatoes at the Source of the Nile
Blog 8: Breeding cassava for the next generation
Blog 9: Paying a visit to the plant doctor in Uganda
Blog 10: Saying goodbye and lessons from the field

Paying a visit to the Plant Doctor in Uganda

Two weeks ago I organised a visit to a plant clinic in the Mukono district of central Uganda. The plant clinics are run by district local government extension staff with support from CABI’s Plantwise programme and offer a place where farmers can bring crop samples to get advice on how to prevent and cure diseases.

Why does Uganda need plant clinics?

It’s estimated that smallholder farmers loose 30 – 40% of their produce to plant health problems before harvest, which threaten food security, income and livelihoods. Ugandan farmers suffer heavily from pests and diseases, including maize stalk borer, wheat rust, banana bacterial wilt, coffee wilt and cassava viral diseases. The situation is always changing, as outbreaks of disease emerge and persist across the country.

Getting access to information is a challenge in rural settings. Often smallholder farmers have very little contact with extension workers and have no way of diagnosing diseases or finding solutions. The plant clinics provide farmers with access to current information to help make rapid, informed decisions that will save their crops. There are now over 191 plant clinics across Uganda and the aim is to have at least one plant clinic in every sub-county by 2020.

On the day…

I was picked up by Benius Tukahirwa an Agricultural Inspector from the Ministry for Agriculture Animal Industry and Fisheries (MAAIF). We drove to Mukono to meet Mukasa Lydia, who’s been a plant doctor for eight years! She has a wealth of plant health knowledge and is in touch with the local community.

When we arrived, we set up a base in the heart of the smallholder village of Nakifuma, Kimenyedde Sub-county, Mukono district. Local farmers find out about the monthly plant clinics through radio announcements and word of mouth. Before long a set of five farmers had arrived with their sickly plant samples. I was told that normally the plant clinics have around 20-50 visitors in a day. On this day the turnout was low as the rains had just started so farmers were in the field planting.

Local famers gather round to hear advice from the plant doctors

Patient 1

The first patient to be examined was a passion fruit branch with “woodiness” viral disease, which causes fruit to become misshapen, woody and inedible. The farmer was told to remove and destroy the infected plants immediately to prevent spread to other plants.

Patient 2

The second patient was a coffee plant with coffee berry disease, a fungal disease which causes coffee berries to rot, turn black and mouldy. The farmer was advised to immediately remove and destroy infected branches, and to apply copper based fungicides to the remaining plants.

Patient 3

The third patient I was very familiar with. The farmer had brought a cassava branch with Cassava brown streak viral disease, the leaves showed characteristic yellow patches and tubers were spoiled and inedible. The plant doctors advised him to get hold of some clean, virus-free planting material from a tolerant variety such as NAROCASS 1, NASE 14, NASE 19 from the government.

Plant patients: passion fruit with woodiness disease (left), coffee wilt disease (middle) and cassava brown streak disease (right)

The farmer: Kayondo Edrissa told me:

“I have been growing cassava for 20 years. I was hard hit in the 90’s by Cassava mosaic disease (CMD), which totally destroyed cassava crops and caused widespread famine. Since the release of CMD resistant varieties people had begun relying on cassava again. But now these varieties have been overcome with Cassava brown streak disease. I’m not going to plant cassava until I get hold of a variety which can resist the disease. Cassava is the real food which can keep our houses going so we really need a solution.”

After the crops were diagnosed, the plant doctors gave clear instructions for how to prevent or cure the diseases in the local language. These instructions were also sent as text messages to the farmers’ phones. Information and images of the diseases were also uploaded to the Plantwise Knowledge Bank so the government can track and respond to outbreaks. There was a challenge in getting a strong enough internet signal to upload the reports.

We then took a tour of Kayondo’s small-holding where we discovered lots of other problems, including a cassava plant with: CBSD, CMD, bacterial wilt and green mites! I was surprised at how many different plant diseases the farmers are facing. The visit helped me to recognise the importance of the clinics; they offer a meeting point for farmers to learn and communicate with each other and trained extension works about similar problems they are facing.

I would like to thank Plantwise for allowing me to visit the clinic, I had a very informative day!

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This blog has been written by University of Bristol Cabot Institute member Katie Tomlinson from the School of Biological Sciences.  Katie’s area of research is to generate and exploit an improved understanding of cassava brown streak disease (CBSD) to ensure sustainable cassava production in Africa.  This blog has been reposted with kind permission from Katie’s blog Cassava Virus.

 

Katie Tomlinson

More from this blog series:  

Blog 1: Getting ready to go… cassava virus hunting!
Blog 2: Week one: Settling in to Ugandan life
Blog 3: Learning the ropes
Blog 4: Clean cassava to solve brown streak problem?
Blog 5: Taking a trip to the cassava field!
Blog 6: Using GM to fight cassava brown streak disease
Blog 7: Talking sweet potatoes at the Source of the Nile
Blog 8: Breeding cassava for the next generation
Blog 9: Paying a visit to the plant doctor in Uganda
Blog 10: Saying goodbye and lessons from the field

Breeding cassava for the next generation

Last week I helped to harvest and score cassava tubers a breeding trial at the National Crops Resources Research Institute (NaCRRI). The trial is part of the NEXTGEN Cassava project which applies genetic techniques to conventional breeding and aims to produce new varieties with Cassava brown streak disease (CBSD) and Cassava mosaic disease (CMD) resistance.

Why cassava and what’s the CBSD problem?

Approximately 300 million people rely on cassava as a staple food crop in Africa. It is resilient to seasonal drought, can be grown on poor soils and harvested when needed. However cassava production is seriously threatened by CBSD, which can reduce the quality of tubers by 100% and is currently threatening the food security of millions of people.

Cassava brown streak symptoms on tubers

Crossing cassava from around the world

Cassava varieties show a huge variation in traits including disease resistance. The NEXTGEN Cassava project has crossed 100 parent plants from Latin America with high quality African plants to produce new improved varieties, with higher levels of CBSD and CMD resistance. Crossing involves rubbing the pollen from one parent variety on to the female flower part (pistil) of the second parent variety to produce seeds.

Cassava flowers used to cross different varieties

 

Cutting back on time

The process is not easy. The complex heritability of traits in cassava means that many plants have to be screened to identify plants with the best traits. To cut down on this time, researchers from Cornell University sequenced the DNA from 2,100 seedlings and selected plants containing sequences linked to desirable traits.

Screening for resistance

These plants were transferred to field site in Namulonge, where there is a high level of CBSD, making it easier to spot resistant plants. After 12 months the tubers were dug up and cut into sections. Each root was scored for the severity of CBSD. Plants which  show no disease symptoms have now been selected for the next stage of breeding. Eventually varieties will be tested for their performance at sites across Uganda and given to farmers for their feedback.

We harvested and scored tubers for Cassava brown streak symptoms. I then tagged disease free plants for selection!

 

Time to harvest!

 

Alfred Ozimati is managing the breeding  programme

I helped to score and tag plants, it was hard work! I was impressed by the stamina of the workers who harvested from 8 am until 3 pm without a rest. I was struck by the mammoth task of breeding cassava for so many traits and by the programme manager Alfred Ozimati’s determination to get the work done as quickly as possible. Alfred is currently a  PhD student at Cornell University; he kindly offered to answer these questions:

What are the challenges of conventional breeding and how does sequencing help to address these?

Typical conventional breeding cycle of cassava is 8-10 years before parents are selected for crossing. The sequencing information allows a breeder to select parents early at the seedling stage, allowing more crossing cycles over time than conventional cassava breeding. With sequencing, the process of releasing varieties with improved CBSD and CMD resistance should take about 5 years.

What are your long term hopes for the project and the future of cassava breeding?

We hope to use genomic selection routinely, to address any other challenges cassava as a crop of second importance to Uganda will face. And also to take the technology to other East African, cassava breeding programs to faster address their major breeding constraints.

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This blog has been written by University of Bristol Cabot Institute member Katie Tomlinson from the School of Biological Sciences.  Katie’s area of research is to generate and exploit an improved understanding of cassava brown streak disease (CBSD) to ensure sustainable cassava production in Africa.  This blog has been reposted with kind permission from Katie’s blog Cassava Virus.

 

Katie Tomlinson

More from this blog series:  

Blog 1: Getting ready to go… cassava virus hunting!
Blog 2: Week one: Settling in to Ugandan life
Blog 3: Learning the ropes
Blog 4: Clean cassava to solve brown streak problem?
Blog 5: Taking a trip to the cassava field!
Blog 6: Using GM to fight cassava brown streak disease
Blog 7: Talking sweet potatoes at the Source of the Nile
Blog 8: Breeding cassava for the next generation
Blog 9: Paying a visit to the plant doctor in Uganda
Blog 10: Saying goodbye and lessons from the field

Talking sweet potatoes at the Source of the Nile

Last month I was invited to the Source of the Nile agricultural trade show in Jinja, Uganda. The show brings together all aspects of agriculture: from crops to chickens, cows and tractors. The event attracts over 120,000 visitors each year and runs for seven days.

I was needed on a National Crops Resources Research Institute (NaCRRI) stand where Agnes Alajo (a PhD student and breeder) was selling improved sweet potato varieties, which are resistant to pests and diseases with higher levels of pro-vitamin A.

It is estimated that around 35% of children and 55% of child-bearing mothers in rural Uganda suffer from vitamin A deficiency, which is associated with preventable child blindness and mortality. The orange-fleshed NAROSPOT varieties developed by NaCRRI are enriched with pro-vitamin A and it’s hoped their adoption will help improve the deficiency problem.

The stand also had an impressive array of biscuits, cakes and even juice made from processing sweet potato. Agriculture is very important in Uganda; it accounts for around 24% of GDP and 43% of the working population are subsistence farmers (2013). Processing sweet potatoes to produce flour can be economically viable and provides farmers with an opportunity to add value to their crop, boost income and reduce poverty.

The range of products made through processing sweet potato

I had to hurriedly absorb information about sweet potato, as very soon hoards of excited school children arrived. The main challenge was that not everyone can speak English and my UK accent was quite difficult for them to understand. I had to speak clearly and slowly to get my message across. Often teachers had to repeat what I had said in their local language. There are over 40 local languages in Uganda, so even Ugandans can find it difficult to communicate!

Agnes explains the importance of pro-vitamin A rich sweet potatoes to school students

Agnes explains the importance of pro-vitamin A rich sweet potatoes to school students
There was a lot of interest from young people who want to pursue agricultural careers and are attracted to opportunities for commercialization. Most people were very intrigued about the cakes, and couldn’t believe that they were made using sweet potato flour. Unfortunately, we couldn’t give out samples to taste until the end of the week, which caused a lot of pleading and disappointment!

Walking around the show I discovered giant cassava tubers, a “speaking head” and impressive looking cabbages. I later  saw the source of the Nile itself!

I had a great time walking around. There was plenty of entertainment and I also got to see where the Nile flows from Lake Victoria!

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This blog has been written by University of Bristol Cabot Institute member Katie Tomlinson from the School of Biological Sciences.  Katie’s area of research is to generate and exploit an improved understanding of cassava brown streak disease (CBSD) to ensure sustainable cassava production in Africa.  This blog has been reposted with kind permission from Katie’s blog Cassava Virus.

 

Katie Tomlinson

More from this blog series:  

Blog 1: Getting ready to go… cassava virus hunting!
Blog 2: Week one: Settling in to Ugandan life
Blog 3: Learning the ropes
Blog 4: Clean cassava to solve brown streak problem?
Blog 5: Taking a trip to the cassava field!
Blog 6: Using GM to fight cassava brown streak disease
Blog 7: Talking sweet potatoes at the Source of the Nile
Blog 8: Breeding cassava for the next generation
Blog 9: Paying a visit to the plant doctor in Uganda
Blog 10: Saying goodbye and lessons from the field

Using GM to fight cassava brown streak disease

Last week I helped plant a new confined field trial for genetically modified (GM) cassava in western Uganda. The aim is to find how well the plants resist Cassava brown streak disease (CBSD).

Before planting, the National Crops Resources Research Institute (NaCRRI) held discussions with people from the local government and farmers’ groups. It’s vital to engage the local community so that people are correctly informed and on-board with the project. There were certainly some very strange myths to debunk!

Henry Wagaba (Head of Biosciences at NaCRRI) explained the huge losses caused by CBSD, which spoils tubers and can wipe out entire fields. CBSD is now the most devastating crop disease in Uganda and there are no resistant varieties currently available.

To fight the disease, NaCRRI researchers have developed GM cassava plants, which show high levels of resistance to CBSD at sites in southern and central Uganda. This trial will test how the plants perform in the growing conditions in western Uganda. Work will also be carried out to cross the GM plants wither farmer varieties to improve their growing and taste qualities.

I enjoyed getting stuck in and planting my first GM cassava!

GM crops are a contentious topic in Uganda. The passing of a National Biotechnology and Biosafety law has stalled in Parliament for over three years due to disagreements. Currently GM technology is used for research on banana, cassava, maize, potato, rice and sweet potato. However these are not approved for human consumption.

In nearby countries Kenya and Sudan, GM food products have been approved and many of these food products are imported into Uganda without regulation. It’s hoped the law will be passed soon to enable Ugandan farmers to reap the benefits of GM crops and protect against any potential risks.

Before the trial, I went on a safari in the Queen Elizabeth National Park, where I saw elephants, hippos and even lions!
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This blog has been written by University of Bristol Cabot Institute member Katie Tomlinson from the School of Biological Sciences.  Katie’s area of research is to generate and exploit an improved understanding of cassava brown streak disease (CBSD) to ensure sustainable cassava production in Africa.  This blog has been reposted with kind permission from Katie’s blog Cassava Virus.

 

Katie Tomlinson

More from this blog series:  

Taking a trip to the cassava field!

At the end of last week I was lucky enough to be invited on a trip to the field. I didn’t really know what to expect but was very excited to find out!

The purpose of the trip was to collect data for the 5CP project to find out how different varieties of cassava respond to Cassava brown streak disease (CBSD) and Cassava mosaic disease (CMD) in different areas.

We set off at 5.30am in the morning; the first stop was Lake Victoria to catch a ferry to the Sesse Islands. The team consisted of me, the driver (Bosco), research assistant (Gerald Adiga) and research technician (Joseph). Along the road, we saw several accidents, sadly a far too common occurrence in Uganda…

Due to delays, the ferry was rammed, and by the time we arrived it was almost the evening. We raced to the agricultural school with the field trial. Here the team have planted blocks of 25 clean cassava varieties from five African countries and our job was to score them for disease symptoms. CBSD and CMD are not very common on the Sesse Islands, and so most of the plants were healthy.

An agricultural student digs up a healthy cassava plant.

After a night of drinking Guinness in a corner shop we headed out, again at 5.30am! This time we headed to the city of Mbarara in the western region. The drive was really beautiful, passing Lake Mburo National Park and mountains covered with matoke.

Whilst scoring the cassava plants here we noticed a super abundance of whiteflies, which carry CBSD viruses. The weather had been particularly dry, allowing the whiteflies to breed like crazy. Fortunately, CBSD is also uncommon in this area and very few plants were diseased.

Super abundance of whiteflies on cassava which carry CBSD viruses.

The data from the 5CP project will help farmers to decide which cassava varieties offer the most protection against CBSD and CMD in their local areas; helping to protect them from the devastating yield losses caused by these diseases.

Fun stuff

On the way back we passed the equator line, and I got the chance to take some touristy photos. This week I also saw the Ndere dance troupe, who showcase the different dance and music styles from all over Uganda and other neighbouring countries. It was a lot of fun, some dances bared a weird resemblance to morris dancing and marching brass bands!

Crossing the equator!
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This blog has been written by University of Bristol Cabot Institute member Katie Tomlinson from the School of Biological Sciences.  Katie’s area of research is to generate and exploit an improved understanding of cassava brown streak disease (CBSD) to ensure sustainable cassava production in Africa.  This blog has been reposted with kind permission from Katie’s blog Cassava Virus.

 

Katie Tomlinson

More from this blog series:  

Clean cassava to solve brown streak problem?

Since arriving in Uganda, I’ve been learning a lot about the affects of Cassava brown streak disease (CBSD), which is devastating cassava production and threatening food security. The disease is spread by the whitefly insect, which picks up the virus from an infected plant and carries it to neighbouring healthy plants.

Cassava plants are grown by planting stem cuttings in the ground, which go on to become new plants. If farmers use cuttings from infected plants, the new plants will also become infected. This is a big problem, as infected cuttings can be transported to new areas, spreading CBSD across large distances.

What can be done?

Tolerance

Huge efforts are being put into a number of different solutions. These include breeding new cassava varieties, which are tolerant to CBSD. This is a very long and challenging process, as cassava plants also need to be resistant to Cassava mosaic disease (CMD) and have yield/taste properties which farmers and consumers prefer.

The National Crops Resources Research Institute (NaCRRI) has recently developed a new variety: NAROCASS1, which is tolerant to CBSD and resistant to CMD. This is now being used in areas where CBSD is particularly common and severe. Unfortunately, even tolerant cassava varieties can contain CBSD viruses and so it’s vital that farmers have access to clean cuttings.

Cassava variety NAROCASS1 with CBSD tolerance and CMD resistance.

Clean seed system (CSS)

The cassava CSS project in Uganda is run by NaCRRI and involves picking the very youngest tip of the cassava plant to produce embryonic tissue, which develops into a new plant. These plants are then checked to see whether the CBSD virus is present before being taken to nurseries where they are carefully multiplied and eventually used for clean planting material for farmers. As you can imagine, this process takes a long time and is much more expensive than taking cuttings from a mature cassava plant. However it means that farmers can benefit from quality assurance that the cuttings they buy are virus free and stand the best chance of remaining healthy.

A clean cassava plantlet produced through tissue culture.

The cassava CSS project has been running as a pilot for three years. It will be very interesting to hear how this project goes, as it’s likely to be a major solution to the CBSD problem.

Reviewing progress

Last week I had helped take minutes for the annual CSS review at NaCRRI, which involved lots of manic typing and concentration! As part of the review I got to visit a field where an entrepreneur is growing clean cassava plants. The plants certainly looked healthy, with no CBSD and CMD symptoms at all. With so much to think about, we still found time to have a cocktail party to let of some steam!

Clean cassava seed entrepreneur David Mpanga explains how he uses record keeping to track of outgoings and income.
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This blog has been written by University of Bristol Cabot Institute member Katie Tomlinson from the School of Biological Sciences.  Katie’s area of research is to generate and exploit an improved understanding of cassava brown streak disease (CBSD) to ensure sustainable cassava production in Africa.  This blog has been reposted with kind permission from Katie’s blog Cassava Virus.

 

Katie Tomlinson

More from this blog series:  

Cassava virus: Journey from the lab to the field – Learning the ropes

Weeks 2 – 3

It’s been a bit of blur the last two weeks, getting to grips with all the activities that go on at the National Crops Resources Research Institute (NaCRRI). I’ve spent time with Dr. Emmanuel Ogwok (Emmy), learning about the earlier days of Cassava brown streak disease (CBSD) research and how things have developed. Emmy took me on a tour to see the greenhouses where they are growing genetically modified cassava, which shows resistance to CBSD.

Dr. Emmanuel Ogwok demonstrates how to sample infected cassava from the field

Diagnosing the problem

Emmy also introduced to me how they diagnose CBSD infections. We headed out to the field and sampled cassava plants showing CBSD symptoms, processed the samples in the lab and bingo, identified the presence of the virus in all the samples by reverse transcription PCR. This is similar to the processes we follow in the UK. It was great to actually sample the infected cassava from the field myself; in the UK we normally use material which was collected years ago.

It was interesting to learn about challenges, such as getting hold of reagents which can take up to three months! The lab is responsible for testing new cassava varieties for their ability to resist CBSD infection and plays a vital role in improving cassava production.

Processing the infected cassava samples from the field

Communicating the problem

I’ve been working on communication materials to let members of the public know about NaCRRI work at the Source of the Nile agricultural trade show in July. The show will be an opportunity to present and discuss the improved cassava varieties developed by NaCRRI with policy makers, growers and members of the public.

Kampala fun

Outside of work, I’ve been having fun in Kampala; going to arts festivals, watching the football in Ugandan pubs and swimming in the Hotel Africana pool. Next week, I’m planning to visit field sites in northern Uganda, to meet some of the farmers affected by CBSD.

Dancer at La Ba Arts Festival (credit HB Visual)
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This blog has been written by University of Bristol Cabot Institute member Katie Tomlinson from the School of Biological Sciences.  Katie’s area of research is to generate and exploit an improved understanding of cassava brown streak disease (CBSD) to ensure sustainable cassava production in Africa.  This blog has been reposted with kind permission from Katie’s blog Cassava Virus.

 

Katie Tomlinson

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Cassava virus: Journey from the lab to the field – Settling in to Ugandan life

Katherine Tomlinson from the School of Biological Sciences at the University of Bristol Cabot Institute, is spending three months in Uganda looking at the cassava brown streak virus. This virus dramatically reduces available food for local people and Katherine will be finding out how research on this plant is translating between the lab and the field.  Follow this blog series for regular updates.

I arrived late on Thursday night and spent the weekend getting acquainted with the hustle and bustle of Kampala life. I visited the impressive Gadafi mosque, cathedral, and food markets, which are full of just about every fruit and vegetable you could imagine.

On Friday, I met with my internship supervisor, Dr. Titus Alicai who is the leader of the Root Crops Research Programme at the National Crops Resources Research Institute (NaCRRI); he filled me on some of the exciting activities I’ll be taking part in, including visits to cassava field sites.

I was picked up and taken to NaCRRI in Namulonge on Sunday, stopping off at markets along the way to pick up my food supplies. I am lucky to have Everline looking after me; she’s helping me to settle into Ugandan life. NaCRRI is absolutely beautiful, it’s full of crops including cassava, sweet potato, mango, pineapple, banana, and there are even vervet monkeys running around.

National Crops Resources Research Institute, Uganda… where I’ll be spending the next three months!

At the start of the week , I was given a tour of the institute including the labs where they analyse cassava tubers for nutritional and chemical content; a vital part of the process in developing crops which not only offer maximum disease resistance, and yield but also taste good.

I then visited the molecular biology labs, where they analyse crop samples for the presence of Cassava brown streak disease viruses. This was very familiar with similar equipment to our lab at the University of Bristol. The lab manager discussed the challenges of obtaining all the expensive reagents required and how this affects their work. Other challenges include intermittent power supply, which means they need a stack of battery packs to back up the -80 freezers and PCR machines. I am looking forward to spending some time here, to learn more about the similarities and differences between molecular work in the UK and Uganda.

On Wednesday, I went to the field with some University internship students, who were scoring cassava plants for Cassava brown streak disease and Cassava mosaic disease symptoms. After their training these students will be able to advise farmers about the diseases in their local areas. It was also my chance to see symptoms in the field, where infected leaves showed a distinctive yellowing pattern.

Inspecting cassava plants for disease symptoms with University internship students

I spoke to one student who has a small farm and has experienced Cassava brown streak disease first hand. He mentioned that the disease is very common in his area, and here even tolerant cassava varieties become infected and their tubers ruined.

Characteristic Cassava brown streak disease symptoms on cassava leaves

Today I am meeting with the communications team, to find out about the projects I will be involved with, including an outreach programme with farmers surrounding the NaCRRI site to encourage them to use crop breeds developed by the institute, which offer higher disease resistance.

That’s it for now I’ll be writing another update next week so watch this space! In the meantime if you have any questions please get in touch via Twitter: @KatieTomlinson4.

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This blog has been written by University of Bristol Cabot Institute member Katie Tomlinson from the School of Biological Sciences.  Katie’s area of research is to generate and exploit an improved understanding of cassava brown streak disease (CBSD) to ensure sustainable cassava production in Africa.  This blog has been reposted with kind permission from Katie’s blog Cassava Virus.
Katie Tomlinson

More from this blog series: