Africa's fairy circle mystery is finally SOLVED: Strange patches in the grassy desert of Namibia are caused by the same toxic saps used in poison arrows.

26 02 2021 | 10:40

Africa's fairy circles in grasslands are formed by a plant that releases a toxic sap into the soil when it dies, a new study reveals.

This poisonous sap, which is used by local bushmen to dip the tips of their hunting arrows, comes from the Euphorbia species of plants.

Researchers say Euphorbia is responsible for bare circular patches in the ground, which are scattered throughout the grassy desert of Namibia and have puzzled the scientific community for decades. 

Between southern Angola and northern South Africa, there are hundreds of thousands of fairy circles, ranging in diameter from seven to 50 feet (2-15 metres).  

Two species of Euphorbia – E. damarana, E. gummifera, and possibly other species like E. gregaria – release the water-repelling sap when they die, inhibiting the growth of other grassy plants and creating barren, featureless circles, experts reveal. 

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A fairy circle in Namibia, Africa. The mysterious circles scattered throughout the grassy desert have long perplexed scientists

Euphorbia death, and therefore the creation of fairy circles, is exacerbated by increasing temperatures, they add.   

The breakthrough study of fairy circles has been conducted by researchers from the University of Pretoria, South Africa and ITMO University in Saint Petersburg, Russia.  

'There are several theories on the cause of the fairy circles,' Professor Marion Meyer from the University of Pretoria's Department of Plant and Soil Sciences, told MailOnline.

'They're so diverse in mechanism because it's such a difficult phenomenon to prove.'

Euphorbia plants are known locally as milk bush for their white, gummy, toxic sap that oozes from its branches.

Euphorbia are succulents – meaning they have thick, fleshy leaves, usually to retain water in arid climates or soil conditions – and can cause permanent blindness in humans if its sap comes into contact with the eyes.  

'I worked with four postgraduate students over several years, approaching it from soil chemistry, biological toxicity and geographical angles,' said Professor Meyer. 

'We are really fully convinced the Euphorbia milk bushes caused, and are still causing them today.' 

Fairy circles are mostly confined to a narrow strip, about 30 to 60 miles (50 to 100 km) inland from the Atlantic Ocean, which stretches down from southwestern Angola, through Namibia to north-western South Africa.  

It was reported in 2017 that fairy circles are partly caused by by 'subterranean ecosystem engineers', such as termites, ants or rodents.

Another possible explanation, known as the known as the 'self-organisation theory', was that competition for water causes plants to position in a way that will allow the roots to best access the flow of rainfall.

'Despite a plethora of research investigating termite activity, soil chemistry, soil hydraulics and other inherent fairy circle properties, there are still a number of different theories attempting to explain their origin and maintenance,' the team say.

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Aerial view of fairy circles, located in the Namib Desert, in the Namib-Naukluft National Park of Namibia

 

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Pictured, Euphorbia gregaria milkbush. Fairy circles of Namibia are caused by dead Euphorbia species, researchers reveal

Due to a lack of scientific evidence of previous theories, Professor Meyer started a multidisciplinary study in 2015 on the effect of Euphorbia species on fairy circle soil chemistry and water.

Euphorbia inhibits germination and also possesses antimicrobial properties against bacteria in the rhizosphere – the portion of soil found adjacent to the roots.  

The plant colonised sandy plains when climatic conditions were more favourable in the past, the researchers propose. 

Since sandy soils have low water-holding capacity, Euphorbia would have been under pressure for water and nutrient availability. 

Gradually over time, as temperatures have risen, the lack of water and competition for nutrients resulted in increased competition between these plants and many would have died. 

The temperature increase in Namibia during the last two or three decades is roughly three times more than the global mean temperature increase reported for the 20th century.  

The decomposition of dead Euphorbia plants and the resulting sticky latex that oozes and disperses out makes the surrounding sandy soil water-repellent (or 'hydrophobic').  

Various other compounds would have also entered the soil from the decaying Euphorbias, which would have had toxic and antimicrobial properties. 

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The fairy circles tend to be found in hotspots in the Namib desert down the east coast of Namibia, as highlighted in the map above

Euphorbia is also allelopathic – the substances it releases inhibits growth of other plants. 

Most of these compounds would probably have broken down in a relatively short time, but the milky latex can adhere to the sand, become hard and can persist in soil for a long time. 

These changes to the soil cause the formation of many fairy circles, causing a transition from a site with only plants, to a mixed site with plants and fairy circles, and then a site only with fairy circles. 

It has been observed that seeds do germinate inside fairy circles and seedlings emerge after good rainfall, but survive only for short periods after rain. 

Euphorbia seedlings in the fairy circles also die because the soil water infiltrates depths beyond their roots. 

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Euphorbia gummifera at Garub near Aus (d) and the same area in a Google Earth image (e)

 

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'Fairy circles' have long been one of nature's greatest mysteries, prompting wild theories they were created by aliens or legendary gods. Pictured, E. damarana co-occurring with fairy circles at Brandberg

However, fairy circles are not permanent, the team suggest – in the course of decades or even centuries, with the occasional rain, the toxicity within the circles will slowly erode away.

This means seedlings will survive for longer periods in the older fairy circles until they are eventually fully established and reach maturity, and the fairy circle will no longer be visible as it's covered by new growth. 

Gas chromatography/mass spectrometry (GC/MS) soil analyses were performed at ITMO University, with the help of Professor Denis Baranenko.

They revealed that soil from both fairy circles, and from under decomposing E. damarana plants, are very similar in phytochemistry. 

Several compounds previously identified with antimicrobial and toxic activity were also identified in E. gummifera, another Euphorbia species. 

Finally, by integrating rainfall, altitude and landcover in in a GIS spatial patterning model, the researchers predicted where fairy circles should occur. 

The model largely agreed with the distribution of three Euphorbia species and resulted in the new discovery of fairy circles in the far southeast of Namibia and even in the Kalahari Desert of South Africa. 

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Site suitability prediction map for fairy circle distribution in Nambia (areas where previously reported fairy circles occur south-west of the Orange River are not included)

 

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A fairy circle taken during sunset in the Namib Naukluft Park. Only from the air is it possible to see their scale and extent

Historical aerial imagery also showed that in a population of 406 E. gummifera plants in southern Namibia, 134 were replaced by fairy circles over a 50-year period. 

This study has provided evidence that Euphorbia can explain the formation of fairy circles at specific sites across Namibia, where these succulents co-occur with fairy circles. 

Further research is now in progress at areas that have many fairy circles but where big populations of euphorbias are currently not present, like in the Namib Rand Nature Reserve and Marienfluss.  

This research will focus on DNA analyses of soil and ancient samples of plant pollen. 

'We’re planning to analyse ancient pollen inside Hyrax midden samples of hundreds to thousands of years old to determine if Euphorbia milk bushes were in those areas and perhaps died out because of climate change,' Professor Meyer told MailOnline. 

The new study has been published in BMC Ecology

 

 

 

17 February 2021

MailOnline