Advanced imaging reveals new fungus species in 407-million-year-old plant fossil from Scotland

Natural History Museum and University of Cambridge researchers have discovered a new species of ancient symbiotic fungus, offering rare 3D insight into early mycorrhizal partnerships between plants and fungi

University of Cambridge

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FLIM returns fluorescence lifetimes that emphasise different features of the plant and fungal structures 

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Credit: Raymond Wightman

Researchers from the Natural History Museum and Sainsbury Laboratory Cambridge University (SLCU) have identified a new species of ancient symbiotic fungus preserved within a 407-million-year-old plant fossil from Scotland. The discovery provides unprecedented three-dimensional insight into one of the earliest known plant–fungus partnerships, known as mycorrhiza.

Beyond this discovery, the advanced microscopy techniques used to distinguish the fungus from the surrounding plant cells open a powerful new way to identify fossilised life forms. By analysing their unique light signatures — a kind of natural fingerprint preserved through time — scientists can detect traces of organisms long after their DNA has vanished.

Published in New Phytologist, the paper describes a new species of arbuscular mycorrhizal fungus, Rugososporomyces lavoisierae, forming a symbiotic relationship with the early land plant, Aglaophyton majus — the second fungal species known to have been hosted by this plant.

The fossil from the Windyfield Chert, Scotland provides the most detailed evidence to date that early land plants engaged in complex symbiotic relationships with multiple fungal species over 400 million years ago. The fossil, held at the National Museum of Scotland, Edinburgh, was prepared and studied by the Natural History Museum’s scientific associate Dr Christine Strullu-Derrien, who co-led the study.

This fossilised relationship was found to closely resemble modern arbuscular mycorrhizal associations that continue to play a vital role in plant nutrition and soil health today.

“Mycorrhizas are very rare in the fossil record and have never been found in the Windyfield Chert before,” said Dr Christine Strullu-Derrien. “The presence of the arbuscule shows that the fungus wasn’t parasitising on the plant or feeding on it after death – instead, there was a symbiotic association. The fungus would have provided minerals like phosphorus in return for sugars from the plant in a way that benefits them both.”

Dr Paul Kenrick, a fossil plant expert at the Museum, and co-author of the study, added: “It’s extraordinary to find such ancient evidence of a symbiotic relationship. It appears that symbioses were a necessary part of allowing plants to adapt to life on land; this symbiosis resembles that observed in modern liverworts or hornworts; these plants like the early land plants don’t have roots. Finding out more about how these relationships developed can contribute to our knowledge of the past, present and future.”

The interdisciplinary team brought together specialists from the Natural History Museum who found the new fungus and conducted brightfield microscopy and confocal microscopy with the Muséum d’Histoire Naturelle in Paris; the Sainsbury Laboratory Microscopy Core Facility, who conducted confocal, fluorescence lifetime imaging microscopy (FLIM) and Raman imaging; and the Cambridge Graphene Centre, responsible for Raman spectroscopy.

The combined use of advanced imaging and spectroscopy applied for the first time to a fossil plant enabled the team to distinguish fossilised fungal and plant tissues based on their unique light signatures, marking a breakthrough that could transform how scientists’ study ancient life in the future. 

“By combining confocal fluorescence lifetime imaging with Raman spectroscopy, we can chemically identify ancient microscopic life forms with remarkable precision. Our new technique is opening an exciting new window on life’s earliest chapters,” said Dr Raymond Wightman, Manager of the Sainsbury Laboratory Microscopy Core Facility who led the FLIM imaging work.

The implications of this discovery extend far beyond the immediate findings. 

“This is just the start,” said Professor Schornack who co-led the study. “By applying these methods to the fossilised remains of different organisms, we now have a powerful new tool to tell apart structures that may look similar but differ in their fine ultrastructure, for example ancient arthropods, plants and fungi.” 

“This technique adds a new dimension to how we identify, describe and discriminate fossilised ancient life, using the unique light signals these materials emit as a kind of fingerprint. Although the original biological material is carbonised and no DNA remains, these optical signatures preserve vital clues to their identity.”

Using these techniques with other fossils from the Windfield and nearby Rhynie cherts, researchers aim to understand how early symbioses evolved and how plants and fungi first learned to coexist.

Reference
Christine Strullu-Derrien, Raymond Wightman, Liam McDonnell, Gareth Evans, Frédéric Fercoq, Paul Kenrick, Andrea Ferrari and Sebastian Schornack (2025) An arbuscular mycorrhiza from the 407-million-year-old Windyfield chert identified through advanced fluorescence and Raman imaging. New Phytologist. DOI: https://doi.org/10.1111/nph.70655

Mycorrhizas in Aglaophyton majus fossil from Windyfield chert

Credit

Victor O.Leshyk

The original thin polished sample of Windyfield chert (left) was placed on a slide and imaged under a Keyence microscope. Zooming in on the sample revealed exquisitely preserved fungal structures, including details of hyphae and arbuscules.

Credit

Gareth Evans

  

Illustration of early land plant Aglaophyton majus.

Credit

Victor O.Leshyk

About the Natural History Museum

The Natural History Museum is a world-leading scientific research centre and one of the world’s most visited museums. Our mission is to create advocates for the planet – people who act for nature. Our 400 scientists are finding solutions to the planetary emergency - from reversing biodiversity loss to resourcing the green economy.  

We are seeking an additional £150 million to transform our South Kensington building: placing our groundbreaking research at its heart, revitalising four existing galleries, opening two new magnificent galleries and delighting 1 million more visitors a year with the wonders of the natural world.    

Media contact:

Natural History Museum Press Office 

Telephone: +44 (0)20 7942 5654 / 07799690151 

Email: press@nhm.ac.uk 

Website: www.nhm.ac.uk

 

About the Sainsbury Laboratory

The Sainsbury Laboratory Cambridge University (SLCU) is dedicated to advancing plant science through cutting-edge research that explores the genetic, molecular, and ecological processes that shape plant life. Located within the Cambridge University Botanic Garden, our state-of-the-art research facility opened in 2011 and was made possible through a generous donation and ongoing core funding from The Gatsby Charitable Foundation. We adopt a multidisciplinary approach to investigate the highly plastic and robust regulatory systems underlying plant growth and development, examining them at scales from the molecular level to ecosystem level, using cutting-edge techniques and technologies. We bring together specialists in biological, physical, and mathematical sciences. This interdisciplinary approach is essential for understanding the complex dynamic and self-organising properties of plants. Quantitative plant science enables us to explore and deepen our fundamental understanding of how plants function.

Media contact:

Kathy Grube (Communications Manager)

Email: kjg45@cam.ac.uk

Telephone: +44 (0) 7709 783 168

Website: www.slcu.cam.ac.uk

 

About the Cambridge Graphene Centre

The Cambridge Graphene Centre (CGC) advances the science and technology of graphene, carbon allotropes, layered crystals, and hybrid nanomaterials. Its mission is to translate pioneering research into real-world applications through close collaboration between academia and industry. The Centre’s state-of-the-art facilities bridge the gap between laboratory discovery and scalable production, enabling the development of printed and flexible electronic devices, energy storage technologies, and smart, connected systems. Research at the CGC is organised around four themes—materials growth and printing, energy, connectivity, and detectors — all aimed at creating energy-efficient, flexible, and multifunctional technologies. The Centre’s work is supported by the Engineering and Physical Sciences Research Council (EPSRC), the Graphene and Quantum Flagships, and the European Research Council.

Media contact:

Cambridge Graphene Centre Department of Engineering, University of Cambridge

Email: info@graphene.cam.ac.uk

Website: www.graphene.cam.ac.uk

 

About New Phytologist  

New Phytologist is a leading international journal focusing on high quality, original research across the broad spectrum of plant sciences, from intracellular processes through to global environmental change. The journal is owned by the New Phytologist Foundation, a not-for-profit organisation dedicated to the promotion of plant science.

Website: https://www.newphytologist.org/ 

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Journal

New Phytologist

DOI

10.1111/nph.70655 

Method of Research

Imaging analysis

Subject of Research

Not applicable

Article Title

An arbuscular mycorrhiza from the 407-million-year-old Windyfield chert identified through advanced fluorescence and Raman imaging

Article Publication Date

12-Nov-2025

 US

New report reveals surge in K–12 data science education nationwide

University of Chicago

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Data Science 4 Everyone today announced the release of its "State of the Field 2025 Data Science and Data Literacy Education in US K-12” report, highlighting rapid growth and new policy initiatives in K–12 data science education across the United States. Building on insights from the National Academies’ September 2022 workshop, this year's issue presents the latest data and case studies on how schools, districts, and states are preparing the next generation for a data-driven world.

“In the AI era, it is essential for students to understand the basic mechanics behind these tools and gain a toolkit to question their outputs as well,” said Data Science 4 Everyone Executive Director Zarek Drozda. “Managers have been asking for data science skills in nearly every sector, and the value of data will only increase over the next decades. We are thrilled to see education leaders taking innovative steps to create these opportunities at long last for students across the country.”

 Key findings include:

• Over 70,000 students enrolled in dedicated data science classes or modules during the most recent school year, spanning 958 schools and 630 districts.
• Eight states, including Arizona, Kentucky, Montana, North Carolina, New York, Tennessee, and the District of Columbia, advanced in Data Science 4 Everyone’s three-tier ranking for policy implementation.
• New Hampshire and Oregon now require credits in data analysis or statistics for high school graduation.
• More than 3,000 teachers nationwide participated in over 23,000 hours of professional development in data science education.

Data Science 4 Everyone continues to advocate for equitable, high-quality data science education, ensuring all students have critical skills for success in higher education, careers, and civic life.

More information and detailed case studies are available in the full report along with an interactive dashboard.

About Data Science 4 Everyone:
About Data Science 4 Everyone is a national coalition committed to ensuring that K–12 students are equipped with the data science and data literacy skills needed to succeed in an increasingly data-driven world. We believe that equitable access to data science education opens doors to higher education, high-paying careers, an engaged community, and a thriving democracy. As new tools and transformative technologies are developed and deployed with increasing speed, it is more essential than ever that our society is fully data literate and prepared to think critically about the origin, collection, modeling, and

presentation of data.

 

Higher methane emissions from warmer lakes and reservoirs may exacerbate worst-case climate scenario

Linköping University

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Professor David Bastviken at Tema M - Environmental Change, Linköping University, Sweden.

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Credit: Charlotte Perhammar

Emissions of the greenhouse gas methane from lakes and reservoirs risk doubling by the end of the century due to climate change according to a new study from Linköping University, Sweden, and NASA Ames Research Center in the US. This in turn could raise Earth’s temperature more than suggested by the UN climate panel IPCC’s current worst-case scenario. 

“This study makes it even clearer that we really, really want to change the climate scenario as quickly as possible. The future will be very uncertain if we don’t,” says Professor David Bastviken at Linköping University, Sweden.

Lakes and water reservoirs are some of the largest sources of methane on Earth. The methane emitted is largely formed as microorganisms decompose organic matter in oxygen-free environments. Before industrialisation, natural methane emissions to the atmosphere were in balance with the methane breakdown processes. If the ongoing climate change disturbs the natural balance causing emissions to increase, global warming is at risk of worsening.

Together with Matthew S. Johnson, Research Scientist at NASA Ames Research Center, David Bastviken has created a model to predict changes in methane emissions from lakes and reservoirs until the end of the century based on IPCC climate scenarios. The model is based on real data from 767 locations in all Earth’s climate zones. It takes into account a variety of factors such as temperature change, changes in the length of emission seasons, different types of flux pathways, different lake and reservoir types, changes in the size of lakes and reservoirs, and nutrient levels. The results have been published in the scientific journal Nature Water.

“We find that temperature changes have by far the greatest impact on future emissions from lakes and reservoirs. Methane formation is very temperature sensitive,” says David Bastviken.

The reason is that rising temperatures speed up microbiological degradation, causing methane emissions to increase exponentially. Researchers’ calculations show that if the IPCC’s warmest climate scenario becomes a reality, current emissions of methane from lakes and reservoirs will almost double by the end of the century. This would increase total global methane emissions by about 10 percent compared to the current level, which would contribute to faster climate change than what is currently expected in the IPCC’s worst-case scenario. 

Even though the situation may look sombre, it is still possible to find something positive in these results, according to David Bastviken. On the one hand, human emissions of mainly carbon dioxide are warming up the planet right now. This indirectly increases the emissions of methane from natural processes, which risks increasing the greenhouse effect even more. On the other hand, reducing human carbon dioxide emissions can have an equally clear opposite effect.

“Any reduction of greenhouse gas emissions from society has a doubling effect. It will prevent the direct warming impact of the emission, and it will also stop a corresponding future increase in methane emissions from lakes and reservoirs,” says David Bastviken.

The research was funded by the European Research Council, the Swedish Research Council, Formas and NASA’s Interdisciplinary Research in Earth Science (IDS) Program and the NASA Terrestrial Ecology and Tropospheric Composition Programs.

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Journal

Nature Water

DOI

10.1038/s44221-025-00532-6 

Method of Research

Computational simulation/modeling

Subject of Research

Not applicable

Article Title

Future methane emissions from lakes and reservoirs

Article Publication Date

4-Nov-2025

COI Statement

BAD NEWS FOR XMAS

Toys contain worrying levels of toxic elements

An analysis of 70 plastic children’s products sold in Brazil revealed chemical contamination in most samples, with levels up to 15 times higher than permitted. Barium, lead, chromium, and antimony were the most commonly found toxic elements.

Fundação de Amparo à Pesquisa do Estado de São Paulo

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Researchers from the University of São Paulo (USP), in collaboration with the Federal University of Alfenas (UNIFAL), have identified high levels of toxic substances in plastic toys sold in Brazil. The study analyzed 70 domestically manufactured and imported products, making it the most comprehensive study ever conducted in Brazil on chemical contamination in children’s products. The results were published in the journal Exposure and Health.

Supported by FAPESP (21/03633-0 and 23/11634-2), the analysis revealed that most toys do not comply with safety standards set by Brazil’s National Institute of Metrology, Quality, and Technology (INMETRO) and the European Union. The most serious case involved barium: 44.3% of the samples exceeded the permitted limit, with concentrations up to 15 times higher than the regulatory value. Exposure to barium can cause cardiac and neurological problems, such as arrhythmias and paralysis.

High levels of lead, chromium, and antimony were also found. Lead, which can cause irreversible neurological damage, memory impairment, and a lower IQ in children, was found above the limit in 32.9% of the samples, with concentrations nearly four times higher than the allowable amount. Antimony, which can cause gastrointestinal damage, and chromium, which is carcinogenic, showed irregularities in 24.3% and 20% of the toys, respectively.

“These data reveal a worrying scenario of multiple contamination and lack of control. So much so that in the study we suggest stricter enforcement measures, such as regular laboratory analyses, product traceability, and more demanding certifications, especially for imported items,” says Bruno Alves Rocha. This work resulted from Rocha’s postdoctoral research, which was supported by FAPESP and was recently completed during his time as a visiting professor at UNIFAL.

For the study, toys were selected to represent different socioeconomic groups. Purchases were made at popular stores and shopping malls in Ribeirão Preto. “We chose toys intended for children aged 0 to 12, many of which were sized and shaped to facilitate oral exploration – that is, they could be put in the mouth – which increases the risk of exposure to toxic substances,” Rocha explained to Agência FAPESP.

The substances were identified and quantified using inductively coupled plasma mass spectrometry (ICP-MS), a technique that can detect trace amounts of metals and non-metals. The investigation also employed a process known as microwave-assisted acid digestion to simulate the release of chemicals through contact with children’s saliva.

This analysis revealed 21 elements with toxic potential: silver (Ag), aluminum (Al), arsenic (As), barium (Ba), beryllium (Be), cadmium (Cd), cerium (Ce), cobalt (Co), chromium (Cr), copper (Cu), mercury (Hg), lanthanum (La), manganese (Mn), nickel (Ni), lead (Pb), rubidium (Rb), antimony (Sb), selenium (Se), thallium (Tl), uranium (U), and zinc (Zn).

Using bioavailability (acid digestion) tests, the researchers set up two exposure scenarios for toxic substances: normal exposure based on median values and high exposure based on maximum values. “Exposure varies according to the concentrations of toxic elements, but it can also vary greatly from one child to another depending on how long they play with or keep the object in their mouth,” says the researcher.

Extraction rates, or the release of substances through contact with gastric juice, ranged from 0.11% to 7.33%. This indicates that only a small fraction of total contaminants are released under conditions that simulate oral exposure. “While this is positive, the finding doesn’t eliminate safety concerns, particularly given the high total concentrations detected in many samples,” says Rocha.

The study also helped map the toy production chain and identify possible sources of contamination. “We found correlations between nickel, cobalt, and manganese, suggesting a common manufacturing origin. Beige-colored toys had higher metal concentrations, possibly due to the paint supplier, which is a relevant clue for future enforcement actions,” he says.

In addition to toxic elements, the group of researchers has investigated the presence of substances capable of interfering with the hormonal system in previous studies. These substances include bisphenols, parabens, and phthalates, which are known as endocrine disruptors.

“This isn’t the first study with such alarming results, which only reinforces the need for urgent action to protect children’s health,” Rocha concludes.

About São Paulo Research Foundation (FAPESP)
The São Paulo Research Foundation (FAPESP) is a public institution with the mission of supporting scientific research in all fields of knowledge by awarding scholarships, fellowships and grants to investigators linked with higher education and research institutions in the State of São Paulo, Brazil. FAPESP is aware that the very best research can only be done by working with the best researchers internationally. Therefore, it has established partnerships with funding agencies, higher education, private companies, and research organizations in other countries known for the quality of their research and has been encouraging scientists funded by its grants to further develop their international collaboration. You can learn more about FAPESP at www.fapesp.br/en and visit FAPESP news agency at www.agencia.fapesp.br/en to keep updated with the latest scientific breakthroughs FAPESP helps achieve through its many programs, awards and research centers. You may also subscribe to FAPESP news agency at http://agencia.fapesp.br/subscribe.

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Journal

Exposure and Health

DOI

10.1007/s12403-025-00731-2 

Article Title

Potentially Toxic Elements in Brazilian Toys: A Bioaccessibility-Based Childhood Health Risk Assessment