A ‘wonder’ fossil changes our understanding of reptile evolution

An international team of researchers has published a breakthrough study in the journal Nature showing that early reptiles from the Triassic period had unique structures growing from its skin that formed an alternative to feathers.

Staatliches Museum für Naturkunde Stuttgart

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Reconstruction and illustration of Mirasaura in its natural forested environment, hunting insects.

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Credit: Gabriel Ugueto

Body coverings such as hair and feathers have played a central role in evolution. They enabled warm-bloodedness by insulating the body, and were used for courtship, display, deterrence of enemies and, in the case of feathers, flight. Their structure is characterised by longer and more complex skin outgrowths that differ significantly from the simple and flat scales of reptiles. Complex skin outgrowths have previously only been observed in mammals in the form of hair and in birds and their closest fossil relatives, dinosaurs and pterosaurs, in the form of feathers. An international team led by palaeontologists Dr Stephan Spiekman and Prof Dr Rainer Schoch from the State Museum of Natural History Stuttgart, Germany, describes a previously unknown tree-dwelling reptile from the early Middle Triassic in a recent study published in the prestigious journal Nature. The 247-million-year-old reptile 'Mirasaura grauvogeli', whose name means 'Grauvogel's Wonder Reptile', had a dorsal crest with previously unknown, structurally complex appendages growing from its skin with some similarities to feathers. The crest was probably used for display to other members of the same species. The find shows that complex skin structures are not only found in birds and their closest relatives but may predate modern reptiles. This important discovery forces us to reconsider our understanding of reptile evolution.

Unique skin structures in early reptiles
The crest of the rather small Mirasaura consists of individual, densely overlapping appendages that each possess a feather-like contour with a narrow central ridge. While real feathers consist of many delicate branched structures called barbs, there is no evidence of such branching in the appendages of Mirasaura. Because of this, the team believes that the structure of the complex, unique skin appendages of Mirasaura evolved largely independently of those of birds.

'The fact that we have discovered such complex skin appendages in such an ancient group of reptiles sheds a new light on their evolution. Mirasaura is even older than the dinosaurs and not closely related to them. Developmental biology studies show that the genetic basis for the growth of complex skin appendages such as feathers probably originated in the Carboniferous period more than 300 million years ago. Mirasaura provides the first direct evidence that such structures actually did form early on in reptile evolution, in groups not closely related to birds and extinct dinosaurs,' says Dr Stephan Spiekman, lead author of the paper and scientist at the State Museum of Natural History in Stuttgart.

Dinosaurs and the origin of feathers
The study marks a turning point in a nearly 30-year trend in palaeontological research that began with the discovery of feathered dinosaurs in China in the late 1990s. Before this time, it was thought that reptiles, including dinosaurs that gave rise to birds, were covered with scales and that only true birds had feathers. As a result, dinosaurs were often depicted as sluggish, scaly animals. This image changed when research started to show that many dinosaurs were much more bird-like than previously thought. The discovery of feathered, non-avian dinosaurs in China caused a wave of new studies that began to blur the lines between scaly, 'cold-blooded' reptiles on the one hand and feathered, 'warm-blooded' birds on the other. Now, it is clear that the story is even more complex.

'Mirasaura grauvogeli shows us how surprising evolution can be and what potential it holds. It repeatedly produces similar structures that are completely independent of each other but also structures that are so different that they can be distinguished. Mirasaura developed an alternative to feathers very early in Earth's history, long before the dinosaurs, which we did not expect and which will stimulate discussion and research,' says Prof. Dr. Rainer Schoch, reptile expert and head of the Palaeontology Department at the State Museum of Natural History in Stuttgart.

Bizarre tree-climbers with bird-like skulls and claws
The latest technologies have been used to study Mirasaura, including synchrotron imaging carried out at the European Synchrotron (ESRF) to reconstruct the skull. This revealed a bird-like shape with a narrow, mostly toothless snout, large forward-facing eye sockets and a large, domed skull. The snout was probably used to extract insects from narrow tree holes. The drepanosauromorphs, to which Mirasaura belongs, are known to palaeontologists as extremely bizarre creatures of the Triassic period. They had grasping forelimbs, sometimes with a huge claw resembling that of a Velociraptor. They had long, barrel-shaped bodies, a long, prehensile tail, and hands that allowed them to grab onto branches like monkeys. Some species even had a hook-shaped claw at the tip of their tail for hanging from branches.

‘Drepanosaurs have many ecological adaptations and have only been known to science for a few decades. Mirasaura lived in trees in one of the first forests that emerged after the great mass extinction at the Permian-Triassic boundary. The dorsal crest with a novel skin structure in Mirasaura adds to the range of remarkable adaptations that make this group of reptiles so unique,’ says palaeontologist Prof Dr Hans Sues from the National Museum of Natural History, Washington DC, USA who participated in the new research.

Melanosomes and skin structures
A thin, brown film was partially preserved on the crest of Mirasaura. Analyses confirmed the presence of melanosomes, tiny organelles that contain melanin pigments. They are found in most animals, including humans. The researchers compared the shape of the Mirasaura melanosomes with those found in the skin of living reptiles, hair and feathers. ‘We know that in modern animals, melanosomes have specific morphologies linked to the tissue where they are found’ says Dr Valentina Rossi, a co-author of the study from University College Cork, Ireland, and an expert on fossil melanosome research. ‘the melanosomes found in Mirasaura soft tissues are more similar in shape to those found in extant and fossil feathers than melanosomes found in mammalian hair and reptilian skin.’

Grauvogel's ‘Wonder Reptile’
Fossil collector Louis Grauvogel began excavating fossils from the Middle Triassic period in Alsace in the 1930s. Among his finds were fossils of Mirasaura. Over the years, he amassed an extensive collection, which remained in the Grauvogel family for many years. In 2019, the collection was transferred to the State Museum of Natural History in Stuttgart, where Mirasaura was discovered during further preparation. The fossils are in the palaeontological collection of the State Museum of Natural History Stuttgart.

Background:

Mirasaura grauvogeli - Discovery story:
Local fossil collector Louis Grauvogel began excavating in Alsace, France, in the late 1930s. The fossils he found dated back to the Middle Triassic period, around 247 million years ago, and consisted mainly of plants, insects and other invertebrates. Unknown to Grauvogel at the time, the finds included the remains of Mirasaura. The collection, which was highly regarded by researchers, remained largely in the family's possession. Dr Léa Grauvogel-Stamm, a palaeobotanist and daughter of Louis Grauvogel, dedicated herself to researching and maintaining the collection. Dr. Grauvogel-Stamm is also involved in the study as a co-author. In 2019, the State Museum of Natural History Stuttgart, Germany, agreed with Dr Lea Grauvogel-Stamm to transfer the extensive collection to Stuttgart. There it will be available for research purposes and will also be on display to the public in future exhibitions. During the preparation of fossils from the Grauvogel Collection in Stuttgart, an unusual small reptile with a crest was discovered and further researched. In honour of its discoverer, Louis Grauvogel, the animal was named Mirasaura grauvogeli - 'Grauvogel's Wonder Reptile'. The fossil is now in the palaeontological collection of the State Museum of Natural History Stuttgart. An interdisciplinary team of palaeontologists wants to further investigate the site where Mirasaura grauvogeli was found to clarify why the skin outgrowths are so well preserved here. Future research will also focus on the ecology, biology and environment of Mirasaura, as well as its interactions with other animals.

State Museum of Natural History Stuttgart:
The State Museum of Natural History Stuttgart is a forward-looking research and communication institute. Its research collections, the archives of diversity, contain over 12 million objects. The museum researches the evolution of life and analyzes the biodiversity of different ecosystems and communicates research findings to the general public.
www.naturkundemuseum-bw.de

Funding:
The research was funded by the DFG - Deutsche Forschungsgemeinschaft (German Research Foundation) and the European Research Council - Consolidator Grant. The State Museum of Natural History Stuttgart was able to acquire the Grauvogel collection several years ago with financial support from the Gesellschaft zur Förderung des Naturkundemuseums Stuttgart e.V., the Cultural Foundation of the German Federal States (Kulturstiftung der Länder) and the Ministry of Science, Research and the Arts Baden-Württemberg.

The holotype of Mirasaura (State Museum of Natural History Stuttgart, Germany) showing the bird-like skull and the crest along the back.





A fossil from the State Museum of Natural History Stuttgart, Germany, preserving the skeleton of Mirasaura.



A fossil from the State Museum of Natural History Stuttgart, Germany, fossil preserving a large crest of Mirasaura.



The reconstruction of the skeleton of Mirasaura.



Credit
Stephan Spiekmann





SEM image of the melanosomes and a schematic drawing of the Mirasaura skin outgrowths


Credit
Stephan Spiekman/ Valentina Rossi


Model of Mirasaura grauvogeli

Credit
Tobias Wilhelm

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Journal

Nature

DOI

10.1038/s41586-025-09167-9 

Subject of Research

Not applicable

Article Title

Triassic diapsid shows early diversification of skin appendages in reptiles

Article Publication Date

23-Jul-2025

Dinosaur tracks show first evidence of multispecies herding

University of Reading

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Footprints of a multispecies herd of dinosaurs discovered in Canada demonstrate the social interaction between different dinosaur species 76 million years ago, according to findings in a new study published today [23 July] in the journal PLOS One.

The new tracksite is the first discovery of its kind in Dinosaur Provincial Park in Alberta, Canada. The Park is world-famous for its abundant fossils but dinosaur footprints were virtually unknown.

The discovery, made during an international field course in July 2024, includes footprints from multiple dinosaur species walking alongside each other – providing the first evidence of mixed-species herding behaviour in dinosaurs, similar to how modern wildebeest and zebra travel together on the African plains.

The researchers were also surprised to find the tracks of two large tyrannosaurs walking side-by-side and perpendicular to the herd, raising the prospect that the multispecies herding may have been a defence strategy against common apex predators. However, more evidence is needed to confirm this.

The international team, led by Dr Brian Pickles (University of Reading, UK), Dr Phil Bell (University of New England, Australia), and Dr Caleb Brown (Royal Tyrrell Museum of Palaeontology, Canada), excavated 29 square metres of the site, revealing 13 ceratopsian (horned dinosaur) tracks from at least five animals walking side by side, with a probable ankylosaurid (armoured dinosaur) walking in the midst of the others.

One footprint of a small meat-eating dinosaur was also discovered. The tracksite extends further into the hillside.

Dr Phil Bell, University of New England, said: “I’ve collected dinosaur bones in Dinosaur Provincial Park for nearly 20 years, but I’d never given footprints much thought. This rim of rock had the look of mud that had been squelched out between your toes, and I was immediately intrigued.

“The tyrannosaur tracks give the sense that they were really eyeing up the herd, which is a pretty chilling thought, but we don’t know for certain whether they actually crossed paths.”

Dr Brian Pickles, University of Reading, said: "It was incredibly exciting to be walking in the footsteps of dinosaurs 76 million years after they laid them down.

“Using the new search images for these footprints, we have been able to discover several more tracksites within the varied terrain of the Park, which I am sure will tell us even more about how these fascinating creatures interacted with each other and behaved in their natural environment.”

Dr Caleb Brown, Royal Tyrrell Museum of Palaeontology, added: "This discovery shows just how much there is still to uncover in dinosaur palaeontology. Dinosaur Park is one of the best understood dinosaur assemblages globally, with more than a century of intense collection and study, but it is only now that we are getting a sense for its full potential for dinosaur trackways."

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Journal

PLOS One

DOI

10.1371/journal.pone.0324913 

Article Title

A ceratopsid-dominated tracksite from the Dinosaur Park Formation (Campanian) at Dinosaur Provincial Park, Alberta, Canada

Article Publication Date

23-Jul-2025

 

Scientists propose AI-driven biotech model for future crop breeding

Chinese Academy of Sciences Headquarters

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Research framework for AI-assisted crop design

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Credit: IGDB

In a major step toward securing global food supplies and advancing sustainable agriculture, a team of scientists has proposed an integrated framework that combines biotechnology and artificial intelligence (AI) to revolutionize crop breeding.

Published in Nature on July 24, the review was co-corresponding authored by Prof. GAO Caixia from the Institute of Genetics and Developmental Biology of the Chinese Academy of Sciences, Prof. LI Guotian of Huazhong Agricultural University, with contributions from additional co-authors including international collaborators.

Facing a rapidly growing global population, intensifying climate change, and shrinking arable land area, ensuring food security and sustainable agriculture is now one of the world's most pressing challenges.

This review explores the integration of multi-omics, genome editing, protein design, and high-throughput phenotyping (HTP) as part of a comprehensive vision for "AI + BT" (biotechnology) integration to genetically improve crops. The authors present a forward-looking framework for AI-assisted crop germplasm design, offering a clear roadmap for the future of sustainable agriculture.

The authors first emphasize the foundational role of modern omics technologies in creating a paradigm shift in crop breeding. They show that advances in genomics, metabolomics, and single-cell omics offer unprecedented insights into the genetic and biological mechanisms influencing crop traits, while revealing precise new targets for trait improvement. They also note that HTP technologies—which leverage drones, sensors, and automation platforms—enable rapid and accurate phenotypic assessments crucial for linking genotypes to phenotypes and identifying valuable genetic variations.

The review also spotlights powerful tools for crop improvement. For example, CRISPR-based genome editing enables efficient and precise genome modification, greatly reducing breeding cycles and enabling the rapid creation and stacking of desirable traits. Meanwhile, AI-driven protein design is emerging as a transformative technology through its capacity to design de novo functional proteins not found in nature. This approach facilitates the development of novel disease-resistance proteins, real-time biosensors for crop monitoring, and custom enzymes for environmental cleanup, thereby endowing crops with transformative traits.

The review particularly focuses on the proposal for an integrative "AI-assisted crop design" model that would use AI to analyze multimodal big data from genomes, phenotypes, environments, and agricultural practices. Breeders would define specific goals—such as increasing yield, enhancing stress tolerance, or improving nutritional quality—while AI would generate optimized, technically actionable breeding strategies through deep learning and knowledge inference. This data-driven approach marks a shift from experience-based breeding to precision design.

The authors also address the challenges ahead. High-quality, standardized data is essential for training robust AI models, and new technologies must comply with biosafety regulations. Encouragingly, global regulatory frameworks for genome-edited crops are evolving toward more scientific and streamlined approaches, paving the way for broader adoption.

This review was supported by the Biological Breeding-National Science and Technology Major Project, the National Key Research and Development Program, the National Natural Science Foundation of China, the Ministry of Agriculture and Rural Affairs of China and the New Cornerstone Science Foundation.

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Journal

Nature

DOI

10.1038/s41586-025-09122-8 

Method of Research

Literature review

Subject of Research

Not applicable

Article Title

Integrated biotechnological and AI innovations for crop improvement

Article Publication Date

23-Jul-2025

 

Youth at risk of suicide show early warning signs that adults often miss

Study finds emotional distress is often overlooked in childhood, suggests need for earlier mental health support in schools

McGill University

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Drawing on a landmark 25-year study that followed Quebec children into adulthood, McGill University researchers have identified two distinct patterns in how suicidal thoughts emerge and the early signs that are often missed.

Suicidal thoughts are increasingly common among youth, but how they begin and what mental health symptoms often precede them are poorly understood, the researchers said.

The study, published in JAMA Psychiatry, analyzed data from the Quebec Longitudinal Study of Child Development, one of only two studies in the world to follow a large group of young people over time and repeatedly track suicidal thoughts.

While most of the 1,600 youth in the study never or rarely reported suicidal thoughts, there were two clear pathways among those who did: about seven per cent began experiencing suicidal ideation in early adolescence (ages 12 to 13), while another five per cent first reported such thoughts for the first time as young adults (ages 20 to 25).

In the early-onset group, many had shown signs of mental health struggles in childhood. These included symptoms like disruptive behaviour, which tend to be more noticeable (external symptoms), and depression and anxiety, which are often harder to detect (internal symptoms).

“A striking finding is that parents and teachers often noticed the behavioural problems but overlooked the internal emotional distress,” said lead author Marie-Claude Geoffroy, associate professor in McGill’s Department of Psychiatry, researcher at the Douglas Research Centre and Canada Research Chair in Youth Suicide Prevention.

In contrast, those whose suicidal thoughts began in young adulthood typically showed only internal symptoms, starting in their teen years.

“When taken seriously, these warning signs can lead to early interventions that could help safeguard children’s development,” said co-author Charles-Édouard Notredame, a child and youth psychiatrist at Lille University Hospital.

Age-appropriate support, including mental health programs in schools, could be especially effective in reaching children and teens at the right time, before suicidal thoughts take hold, he added.

Suicide is the second leading cause of death among youth and young adults in Canada, according to national data.

“Suicidal ideation in youth is still too often dismissed as a ‘phase’ that will pass,” said Geoffroy. “Our findings highlight the need to start suicide prevention early."

About the study

“Mental Health Antecedents and Correlates of 2 Distinct Developmental Pathways to Suicidal Ideation” by Marie-Claude Geoffroy, Sasha MacNeil and Vincent Paquin et al., was published in JAMA Psychiatry.

This research was supported by Quebec’s ministries of Health, Families, Education and Higher Education, the Lucie and André Chagnon Foundation, the Institut de la statistique du Québec, the Fonds de recherche du Québec, the Social Sciences and Humanities Research Council of Canada and the Canadian Institutes of Health Research.

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Journal

JAMA Psychiatry

DOI

10.1001/jamapsychiatry.2025.1273 

Method of Research

Data/statistical analysis

Subject of Research

People

Article Title

Mental Health Antecedents and Correlates of 2 Distinct Developmental Pathways to Suicidal Ideation

Article Publication Date

2-Jul-2025

 

California Latino GDP surges past $1 trillion, as Latinos help power state economy

UCLA and Cal Lutheran report shows that California Latinos also account for almost a fourth of the total U.S. Latino GDP

University of California - Los Angeles

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Key takeaways

• California's Latino GDP surpassed $1 trillion in 2023. 

• Without Latinos, California’s GDP, which represented the fifth-largest global economy in 2023, would have fallen to eighth. 

• In 2023, 41% of working-age Latinos living in the state were immigrants.

Earlier this year, the latest U.S. Latino GDP Report revealed that the direct economic output of the country’s Latino population exceeded $4 trillion for the first time. Now, new findings from researchers at UCLA and California Lutheran University show that a quarter of that came from Latinos in one state: California. 

“Latinos have been driving California’s economy for 250 years,” said co-author David Hayes-Bautista, a distinguished professor of medicine at UCLA and the report’s co-author.

The California Latino GDP Report, which looks at the economic contributions and performance by Latinos in 2023, showed that Latinos significantly enhanced California’s output. 

“The importance of rapid Latino growth rates, and the intensity of economic activity which they represent, cannot be overstated,” said Matthew Fienup, executive director of the Center for Economic Research & Forecasting at Cal Lutheran and co-author of the report. “The vitality of the overall California economy greatly depends on the intensity of the economic activity of Latinos.”

The impact of the Latino GDP is bolstered by several key factors, such as: 

• The Latino labor force in California is growing at a rate 15 times faster than the non-Latino labor force. 
• Educational attainment by Latinos is growing 3.4 times faster than that of non-Latinos. 
• California Latinos are 5.6 percentage points more likely to be actively working than their non-Latino counterparts. 
• Researchers also found that Latinos enjoy better health outcomes, with lower age-adjusted mortality across all five leading causes of death, and a life expectancy that is more than two years longer than non-Latino whites.

California’s Latino economy is also more diversified than the overall state economy. The top industries Latinos are involved in, researchers found, were sectors defined as finance and real estate; professional and business services; government services; education and health care; and retail trade. In finance and real estate, Latinos produced over $137 billion in economic output.

The study's findings highlight the importance of California’s Latino immigrant population in the state’s economy. In 2023, 41% of working-age Latinos living in the state were immigrants. After applying that share to the California Latino GDP, the researchers estimate that Latino immigrants may be responsible for as much as $400 billion in annual economic output in California.

California had an overall GDP of nearly $3.9 trillion in 2023, according to previously released information from the governor’s office. Without the $1 trillion Latino GDP in the overall state GDP, California, when compared to countries, would fall from being the fifth-largest global economy in 2023 to eighth.

Hayes-Bautista, who co-founded the research initiative and serves as the director of the Center for the Study of Latino Health and Culture, emphasized the significance of supporting Latino youth, especially since strong GDP growth leads to rising wages, higher standards of living and greater economic mobility not just for Latinos, but for all.  

“The state needs to maximize its investment in young Latinos’ health and education,” he said. “Anything that detracts from that investment detracts from California’s future.”

The new report is part of a larger research initiative that documents the rapidly growing economic contributions of Latinos in the United States. In addition to the annual national reports and the inaugural Latina GDP report, the researchers have also taken more detailed looks at major metropolitan areas and other states, such as Florida, Arizona and Texas. 

 

New study reveals coral reef food webs are more siloed and vulnerable than previously understood

University of Rhode Island

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Sampling snapper on coral reefs to assess their role in complex reef food web dynamics.

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Credit: Simon Thorrold

KINGSTON, R.I. —July 23, 2025 — A study led by Associate Professor Kelton McMahon at University of Rhode Island’s Graduate School of Oceanography has found that food webs on tropical reefs are more fragile than we once thought. Instead of being part of a highly connected system where species can easily switch food sources, many reef creatures in these incredibly biodiverse ecosystems rely on surprisingly narrow, specialized energy pathways that link specific species to distinct sources of primary production.

Using compound-specific stable isotope analysis of amino acids (CSIA-AA), a cutting-edge technique McMahon helped pioneer that allows scientists to follow the path of nutrients as they flow through ecosystems over time, the team investigated three common reef-dwelling snapper species (Lutjanus kasmira, L. ehrenbergii, and L. fulviflamma). Though previously considered opportunistic predators, these fishes, and the food webs supporting them, turned out to be remarkably specialized:

• Lutjanus kasmira fed almost exclusively within a food web based on water column phytoplankton.
• L. ehrenbergii was tied to a macroalgae-based food web on the seafloor.
• L. fulviflamma primarily fed within a coral-based food web.

“When you dive on these beautiful Red Sea reefs, one of the first things that you’ll notice is these snapper species schooling together in perfect synchrony. We would never have guessed that each had carved out its own unique niche within these complex, biodiverse reef food webs.” said McMahon as he reflected on his first time diving on the study reefs. As abundant predators high in the food chain, they were long assumed to be generalists, roaming the reef together and feeding broadly on whatever prey was available.

But the study findings reveal a shockingly different story: the flow of energy from primary producers low on the food chain (like coral, macroalgae, and phytoplankton) to predators is highly compartmentalized. In other words, each species relies on a distinct “silo” of production, forming self-contained food chains within specific microhabitats on the reef, despite the ability and opportunity to feed on a much broader array of potential prey. “It’s one thing to see a species or two specializing on a specific food item, but to see entire food chains of potentially dozens or even hundreds of species form tight relationships connected to a single primary producer (e.g., macroalgae) when equally tasty coral is just inches away fundamentally reshapes how we think about biodiversity of coral reefs.” says McMahon.

Implications for reef resilience and biodiversity

The study also sheds light on a classic ecological puzzle: how high species diversity persists in reef environments historically characterized as low in nutrients, particularly in warm, shallow tropical waters. Normally, we’d expect stable ecosystems to have a lot of overlap in where energy comes from, helping them bounce back from disruptions. But instead, this study shows that reef species often stick to their own isolated energy sources, what the researchers call “vertical silos.”

This kind of separation within reef ecosystems challenges long-held assumptions that coral reefs are naturally resilient because they have so many species serving similar, interconnected roles. In systems where multiple species can perform the same role, the loss of one part doesn’t necessarily collapse the whole. But in these vertically siloed reef food webs, if a single primary producer is disturbed by climate change, overfishing, or bleaching, it can fracture an entire food chain.

That makes coral reef food webs more structured and more fragile than we thought, offering new insight into how these ecosystems work, and how vulnerable they may be to rapid environmental change.

Novel methods: CSIA-AA

McMahon’s Ocean Ecogeochemistry Lab on the URI Narragansett Bay Campus uses stable isotopes to understand the life history of animals based on what they’ve eaten. The lab’s research dives into big questions about food security, coastal health and resilience, and how warming waters are redistributing ocean life. In this study, the team used CSIA-AA to trace how carbon and nitrogen move through the coral reef food web. Unlike traditional methods like stomach content analysis, which only offer a short-term snapshot of what an animal has eaten, CSIA-AA provides a longer-term, more precise view of how energy actually flows through an ecosystem.

“People have used isotopes to understand food webs for nearly a century, where they turn an organism into a single isotope value. I’ve spent my career developing knowledge and tools to isolate and analyze all individual compounds within complex organisms, unlocking a metabolic history of organisms in a way we have never done before. That gives us the power to track where different sources of energy come from, and, in doing so, reveal patterns in the food web we couldn’t see before,” says McMahon about the novel CSIA-AA methodology.

Patience is key

The samples used in this study were collected during fieldwork in the Red Sea, with fish tissue analyzed at GSO and partner labs including the Woods Hole Oceanographic Institution. McMahon noted that samples were archived for over a decade before advances in analytical tools made this analysis possible:

“I collected these samples 15 years ago as a postdoc at King Abdullah University of Science and Technology,” shared McMahon. “The data were there, but I didn’t yet have the tools or perspective to make sense of it in a meaningful way. Sometimes, you have to let an idea sit until the knowledge and methods mature enough to be impactful. Finally, I feel prepared to handle this work in the way it deserves, and the outcome definitely rewarded that patience.”

The team plans to expand this work to other reef systems, explore similar questions in kelp forests and deep-sea ecosystems, and integrate DNA metabarcoding to more precisely identify the prey species that connect these highly siloed energy channels.

“I get excited about opening up access to knowledge that people have been seeking for a long time,” McMahon added. “In my lab, we don’t specialize on a system or species; we’ve worked in Antarctica with penguins, on ancient human diet in MesoAmerica, and locally with the burgeoning jonah crab fishery. Our goal is to develop tools that solve vexing ecological problems, and make sure diverse people and approaches are effectively brought together.”

Citation: McMahon KW, Thorrold SR, Langan JA, Pi J, Berumen ML, 2025. Highly siloed nutrient pathways fuel meso-predator fishes on coral reefs, Current Biology (2025)

This story was written by Mackensie duPont Crowley, a digital communications coordinator in URI’s Graduate School of Oceanography.

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Journal

Current Biology

DOI

10.1016/j.cub.2025.06.034