Monday, April 20, 2026

 

Cocaine pollution alters salmon behaviour in the wild




Griffith University

Salmon group 

image: 

A new study has revealed cocaine pollution changed how wild fish moved through their environment, with juvenile Atlantic salmon swimming farther and dispersing more widely.

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Credit: Jörgen Wiklund





The international study, led by researchers from Griffith University, the Swedish University of Agricultural Sciences, Zoological Society of London and Max Planck Institute of Animal Behaviour, is the first to demonstrate the effects of cocaine contamination on fish behaviour in the wild rather than in laboratory conditions.

To understand how these pollutants influenced animal movement, the researchers used slow-release chemical implants and acoustic telemetry tracking to monitor 105 juvenile Atlantic salmon over eight weeks in Lake Vättern, Sweden.

The fish were assigned to one of three treatment groups: a control group, a group exposed to cocaine, and a group exposed to benzoylegonine, the primary metabolite of cocaine that is commonly detected in wastewater.

The team found fish exposed to benzoylecgonine swam up to 1.9 times farther per week than unexposed fish and dispersed up to 12.3km farther across the lake.

These changes became more pronounced over time, indicating that exposure altered how fish used space in a complex natural ecosystem

Co-author Dr Marcus Michelangeli, from Griffith University’s Australian Rivers Institute, said the findings were important because movement played a central role in how animals interacted with their environment.

“Where fish go determines what they eat, what eats them, and how populations are structured,” he said.

“If pollution is changing these patterns, it has the potential to affect ecosystems in ways we are only beginning to understand.”

Cocaine and its metabolites were increasingly detected in rivers and lakes around the world, primarily entering waterways through wastewater systems that were not designed to fully remove these compounds.

While previous research has shown cocaine could affect animal behaviour, those studies had been limited to laboratory settings.

This study provides the first evidence that these effects also occurred in the wild, where animals experienced far more complex environmental conditions.

The researchers also found the cocaine metabolite benzoylecgonine had a stronger effect on fish movement than cocaine itself.

This was significant because risk assessments typically focused on the parent compound, even though metabolites were often more common in waterways, suggesting current approaches may overlook important biological effects.

The team emphasised the findings did not indicate a risk to people consuming fish.

The exposure levels reflected those already found in polluted waterways, the compounds break down over time, and the fish studied were juveniles well below legal-catch size.

Dr Michelangeli said the study highlighted a broader issue about the types of pollutants entering aquatic ecosystems.

“The idea of cocaine affecting fish might seem surprising, but the reality is that wildlife is already being exposed to a wide range of human-derived drugs every day,” he said.

“The unusual part is not the experiment, it’s what’s already happening in our waterways.”

Future research would aim to determine how widespread these effects were, identify which species were most at risk, and test whether altered movement patterns translated into changes in survival and reproduction.

The paper ‘Cocaine pollution alters the movement and space use of Atlantic salmon (Salmo salar) in a large natural lake’ has been published in Current Biology.

 

How primitive plants evolved to survive Earth’s most catastrophic extinction event



University of Leeds





Images available via Dropbox link here 

How primitive plants evolved to survive Earth’s most catastrophic extinction event  

Earth responded to its most severe past warming event by evolving a new and bizarre type of photosynthesis that allowed a group of primitive plants to survive. 

Research led by the University of Leeds has revealed how lycophytes - a type of ancient plant - not only survived a mass extinction 250 million years ago but then came to dominate the recovering landscapes. 

During the Permian-Triassic mass extinction, which is also known as the “Great Dying,” global temperatures rose dramatically with most forests collapsing under extreme heat and vast areas of land becoming barren. 

The study, which is published today (20 April) in the journal Nature Ecology and Evolution , concludes that lycophytes conserved water and tolerated heat by opening their stomata at night instead of during the day, storing CO2 as an acid to use in the daytime for photosynthesis.  

The researchers believe lycophytes may have been the first plants to use this mechanism revealing a biological innovation that was able to keep Earth’s biosphere active with the plants able to remove carbon from the atmosphere, ultimately combating the effects of the warming event. 

Today, plants using CAM photosynthesis make up only a small proportion of global vegetation and are most common in hot and dry environments such as deserts. 

Lead author of the study, Dr Zhen Xu from Leeds’ School of Earth and Environment, said: “Our results suggest that under future warming, plants with CAM photosynthesis traits could become far more important.  

“If the world experiences sustained extreme heat, plant communities may shift toward species that are better able to tolerate high temperatures and water stress.” 

Lycophytes are spore-bearing vascular plants (a type of plant characterised by the presence of tissues for transporting water and nutrients). There are more than 1,200 species of the plant still in existence. They can survive in many places but are most diverse in tropical regions.   

To understand how lycophytes survived when so many other plants perished, the researchers first studied their evolutionary relationships to find their closest relatives, such as the quillworts that can still be found around the world, including in Scotland. They then studied carbon isotopes (variants of carbon atoms) in fossil plants from South China from the late Permian to the Middle Triassic period. Different types of photosynthesis leave different carbon isotope signatures, so this can reveal how ancient plants functioned. 

They found that lycophytes had carbon isotope values that were noticeably different from other plants during the Permian–Triassic extinction period. This difference became smaller once environmental conditions had improved. 

The team then compared where the lycophyte fossils were found with climate model simulations. The results suggest that these plants lived in places where surface temperatures likely exceeded 50 °C. 

The researchers believe increased knowledge about Earth’s geological past can help to inform predictions about future climate resilience, something which they say is becoming increasingly important in a warmer world. 

Co-author of the study, Professor Barry Lomax of the University of Nottingham, said: "The analysis pulled together many separate scientific disciplines to test how this group of enigmatic plants not only survived the great dying but also how they were able to thrive in a highly stressed environment. 

“By linking these data together, we are able to further understand plant adaptation to past climate emergencies deepening our understanding of the resilience of the Earth system to climate perturbations." 

Professor Benjamin Mills from Leeds’ School of Earth and Environment added: “Understanding how plants’ diverse physiological strategies shaped ecosystems in the past helps us to anticipate how vegetation might reorganize in the future, and because plants are the base of terrestrial food webs, changes in dominant plant strategies can alter the functioning of the entire Earth system.” 

Ends 

Further information 

CAM photosynthesis may have conferred an advantage during the Permian-Triassic mass extinction event is published today (20 April) in Nature Ecology and Evolution. The DOI is 10.1038/s41559-026-03026-0 

The research was led by the University of Leeds in partnership with: 

  • China University of Geosciences (Wuhan) 

  • University of Birmingham 

  • University of Nottingham 

  • University of Bristol 

  • Institute of Tibetan Plateau Research, Chinese Academy of Sciences 

  • University of California, Davis 

Images available via Dropbox link here Please credit Dr Zhen Xu 

Image one shows fossil hunting in south China. 

Images two and three show lycophyte reproductive cones, belonging to the genus Lepacyclotes.  

For media enquiries, please contact the University of Leeds press office via pressoffice@leeds.ac.uk 

University of Leeds 

The University of Leeds is one of the largest higher education institutions in the UK, with more than 40,000 students from about 140 different countries. We are renowned globally for the quality of our teaching and research. 

We are a values-driven university, and we harness our expertise in research and education to help shape a better future for humanity, working through collaboration to tackle inequalities, achieve societal impact and drive change.  

The University is a member of the Russell Group of research-intensive universities, and is a major partner in the Alan Turing, Rosalind Franklin and Royce Institutes www.leeds.ac.uk  

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New genetic evidence from Stajnia Cave reveals the oldest Neanderthal group reconstructed in Central-Eastern Europe





Università di Bologna
Aerial view of Stajnia Cave 

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The study presents the results of the analysis of ancient mitochondrial DNA obtained from eight Neanderthal teeth discovered in Stajnia Cave, Poland.

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Credit: M. Żarski, Polish Geological Institute





An international study published in Current Biology presents the results of the analysis of ancient mitochondrial DNA obtained from eight Neanderthal teeth discovered in Stajnia Cave, Poland. For the first time, the research reconstructs the genetic profile of a small group of Neanderthals from the same site, north of the Carpathians, who lived during the same ancient chronological phase.

“This is an extraordinary result because, for the first time, we are able to observe a small group of at least seven Neanderthals from Central-Eastern Europe who lived around 100,000 years ago,” says Andrea Picin, professor at the University of Bologna and coordinator of the research. “In most cases, Neanderthal genetic data come from single fossils or from remains scattered across different sites and periods. At Stajnia, by contrast, it has been possible to reconstruct a small group of individuals, providing for the first time a coherent genetic picture of Neanderthals in this part of Europe.”

“We had known for some time that Stajnia Cave preserved exceptional evidence, but these results exceeded our expectations,” say Wioletta Nowaczewska of the University of Wrocław and Adam Nadachowski of the Institute of Systematics and Evolution of Animals of the Polish Academy of Sciences, co-authors of the study. “Being able to identify such an ancient small group of Neanderthals in such a complex site is an important achievement for Polish research and for the study of Neanderthals in Europe.”

The discovery also helps us better understand the distribution of a particular Neanderthal maternal lineage in western Eurasia. The mitochondrial DNA of the Stajnia Neanderthals falls within the same branch as that of other individuals found in the Iberian Peninsula, south-eastern France, and the northern Caucasus, suggesting that this genetic component was widely distributed before being replaced by those typical of more recent Neanderthals.

“A particularly fascinating aspect is that two teeth belonging to juvenile individuals and one belonging to an adult share the same mitochondrial DNA,” adds Mateja Hajdinjak, co-author of the article and researcher at the Max Planck Institute for Evolutionary Anthropology. “This suggests that these individuals might be closely related to each other.”

Another important aspect of the study concerns the comparison with the Neanderthal fossil Thorin, discovered in Mandrin Cave in France, which carries a mitochondrial genome similar to that of the Stajnia Neanderthals and has so far been assigned to a chronology of around 50,000 years ago. “Our study is a reminder that the oldest chronologies must be treated with great caution,” explains Sahra Talamo, professor at the University of Bologna and co-coordinator of the study. “When radiocarbon values approach the limit of calibration, it is essential not to assign more precision than the data can actually support. In such cases, the comparison between archaeology, radiocarbon dating, and genetics becomes crucial.”

From an archaeological point of view, the discovery reinforces the idea that Central-Eastern Europe was not a marginal periphery in Neanderthal history, but rather a key area for understanding population movements, biological connections, and the spread of technological traditions during the Middle Paleolithic. Stajnia Cave and southern Poland thus become a privileged observatory for reconstructing not only the biology of Neanderthals, but also their movements and the connections between groups distributed across wide areas of Europe.


For the first time, the research reconstructs the genetic profile of a small group of Neanderthals from the same site, north of the Carpathians, who lived during the same ancient chronological phase.

Credit

Max Planck Institute for Evolutionary Anthropology

 

Stone age population collapse revealed by DNA study in France






University of Copenhagen






The research, published in Nature Ecology & Evolution, is based on genetic analyses of 132 individuals buried in a large megalithic tomb near Bury, about 50 kilometres north of Paris. The site was used during two distinct periods separated by a population decline around 3000 BC.

Researchers found that the two groups buried before and after the decline were not genetically related, pointing to a major population turnover.

“We see a clear genetic break between the two periods,” said Frederik Valeur Seersholm, assistant professor at the Globe Institute at the University of Copenhagen and one of the lead authors of the study.

“The earlier group resembles Stone Age farming populations from northern France and Germany, while the later group shows strong genetic links to southern France and the Iberian Peninsula.”

The findings suggest a sharp reduction in the local population followed by the arrival of new groups from the south.

Disease and high mortality

Using a DNA method that analyses all genetic material preserved in bone, the researchers detected traces of ancient pathogens, including the plague bacterium Yersinia pestis and louse-bourne relapsing fever caused by Borrelia recurrentis.

“We can confirm that plague was present, but the evidence does not support it as the sole cause of the population collapse,” said Martin Sikora, associate professor at the University of Copenhagen and senior author of the study. “The decline was likely driven by a combination of disease, environmental stress and other disruptive events.”

Archaeological analysis of the skeletal remains shows unusually high mortality in the earlier burial phase, particularly among children and young people.

“The demographic pattern is a strong indicator of crisis,” said Laure Salanova, research director at France’s National Centre for Scientific Research (CNRS).

Shift in social organisation

The DNA data also reaffirm a marked change in social structure.

In the earlier phase, multiple generations from the same extended families were buried together, suggesting tightly knit communities. In the later phase, burials were more selective and dominated by a single male lineage, pointing to a different form of organisation.

“This indicates that the population change was accompanied by a shift in how society was structured,” Seersholm said.

A wider European pattern

The findings add to growing evidence that the so-called Neolithic decline affected much of northern and western Europe, not only Scandinavia and northern Germany.

The study also offers a possible explanation for why the construction of megalithic tombs and other large stone monuments ended across Europe around the same time.

“We now see that end of these monumental constructions coincides with the disappearance of the population that built them,” Seersholm said.

 

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