Fighting A Destructive Crop Disease With Mathematics

Jun 21, 2017

This is a maize field in Kenya.

An international team of researchers has used mathematical modelling to understand new ways of combating maize lethal necrosis, an emerging disease that poses a serious threat to food security in sub-Saharan Africa.

Maize lethal necrosis (MLN) arises from the interaction of two viruses: maize chlorotic mottle virus (MSMV) and a virus from a group named potyviruses, often sugarcane mosaic virus (SCMV). But traditional modelling has focused on understanding just one virus at a time. By modelling the spread of these two co-infecting viruses together, within and between growing seasons, the team has shed new light on the disease that will help farmers to manage it effectively.

The study, published this week in the journal Phytopathology, demonstrates that a combination of crop rotation, using virus-free 'clean seed', roguing (removing plants showing disease symptoms) and controlling insect pests is the best way to control MLN. It also highlighted differences in the ability of large and small growers to prevent loss of their maize crop.

"Larger growers have more money for insecticides and buying clean seed, both of which can greatly reduce disease levels. Crop rotation - an important component of control for smaller growers - disrupts transmission from season to season, but it requires coordination between farmers to ensure the virus doesn't build up in surrounding fields. Unless significant investment is made in farmer training, this unfortunately remains more realistic for larger farmers, who tend to be better organized and to have larger growing areas," said Dr Nik Cunniffe, an expert in mathematical biology based in Cambridge's Department of Plant Sciences, who contributed to the work.

Modelling the effects of two viruses infecting the same plant is rarely done, despite this happening frequently in the real world. The approach is highly relevant for other regions of the world where Maize Lethal Necrosis is an emerging threat to maize production, such as South East Asia and South America. It could also inform the management and control of other destructive plant diseases caused by combinations of pathogens, such as sweet potato virus disease in Africa and rice tungro disease in Asia.

"We've developed a new framework to model co-infecting viruses, such as those causing Maize Lethal Necrosis, even when there's not very much biological information available. When two viruses infect a plant they can interact with each other to cause much worse symptoms and greater losses of yield. If you're a subsistence farmer relying on income from the maize you're growing, infection of the crop with MLN can be devastating," Cunniffe said.

Maize is one of sub-Saharan Africa's staple food crops, and MLN has been spreading in Kenya for the last six years, causing devastating harvest losses of up to 90% in heavily affected regions. This affects not only direct availability of food, but also local income and employment. The study focused on Maize Lethal Necrosis disease in Kenya, where crop losses are particularly high, although the disease has spread to other countries in Africa. Infected corn plants die prematurely or are frequently barren, drastically reducing the yield. Most of the nation's maize supply comes from small to medium-size farms, which are less able to withstand threats to their food production than large resource-rich farms.

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Video: Spring 2026 weather outlook for Wisconsin; What an early-arriving El Niño could mean

Northeast Wisconsin is a small corner of the world, but our weather is still affected by what happens across the globe.

That includes in the equatorial Pacific, where changes between El Niño and La Niña play a role in the weather here -- and boy, have there been some abrupt changes as of late.

El Niño and La Niña are the two phases of what is collectively known as the El Niño Southern Oscillation, or ENSO for short. These are the swings back and forth from unusually warm to unusually cold sea surface temperatures in the Pacific Ocean along the equator.

Since this past September, we have been in a weak La Niña, which means water temperatures near the Eastern Pacific equator have been cooler than usual. That's where we're at right now.

Even last fall, the long-term outlook suggested a return to neutral conditions by spring and potentially El Niño conditions by summer.

But there are some signs this may be happening faster than usual, which could accelerate the onset of El Niño.

Over the last few weeks, unusually strong bursts of westerly winds farther west in the Pacific -- where sea surface temperatures are warmer than average -- have been observed. There is a chance that this could accelerate the warming of those eastern Pacific waters and potentially push us into El Niño sooner than usual.

If we do enter El Nino by spring -- which we'll define as the period of March, April and May -- there are some long-term correlations with our weather here in Northeast Wisconsin.

Looking at a map of anomalously warm weather, most of the upper Great Lakes doesn't show a strong correlation, but in general, the northern tiers of the United States do tend to lean to that direction.

The stronger correlation is with precipitation. El Niño conditions in spring have historically come with a higher risk of very dry weather over that time frame, so this will definitely be a transition we'll have to watch closely as we move out of winter.